Hybrid winter oilseed rape and methods for producing same

ABSTRACT

This invention relates to transgenic winter oilseed rape (WOSR) plants, plant material and seeds, characterized by harboring a specific transformation event. It pertains to winter oilseed rape plants, more particularly to a pair of winter oilseed rape plants, which is particularly suited for the production of hybrid seed. More specifically, one plant is characterized by being male-sterile, due to the presence in its genome of a male sterility gene. The invention further provides a method for producing hybrid seed, a process for producing a transgenic WOSR plant oil or plant, and a method to identify a transgenic plant, cell or tissue. A kit for identifying the transgenic plants comparing the elite event of the present invention is also described. The WOSR plants of the invention combine the ability to form hybrid seeds with optimal agronomic performance, generic stability and adaptability to different generic backgrounds.

FIELD OF THE INVENTION

This invention pertains to winter oilseed rape (WOSR) plants, more particularly a pair of winter oilseed rape plants, which is particularly suited for the production of hybrid seed. More specifically, the one plant is characterized by being male-sterile, due to the presence in its genome of a male-sterility gene, while the other is characterized by carrying a fertility-restorer gene, capable of preventing the activity of the male-sterility gene. The pair WOSR plants of the invention combine the ability to form hybrid seed with optimal overall agronomic performance, genetic stability and adaptability to different genetic backgrounds.

All documents cited herein are hereby incorporated herein by reference.

BACKGROUND OF THE INVENTION

The phenotypic expression of a transgene in a plant is determined both by the structure of the gene itself and by its location in the plant genome. At the same time the presence of the transgene at different locations in the genome will influence the overall phenotype of the plant in different ways. The agronomically or industrially successful introduction of a commercially interesting trait in a plant by genetic manipulation can be a lengthy procedure dependent on different factors. The actual transformation and regeneration of genetically transformed plants are only the first in a series of selection steps which include extensive genetic characterization, breeding, and evaluation in field trials.

Oilseed rape (OSR)(Brassica napus, AACC, 2n=38) is a natural hybrid resulting from the interspecies hybridisation between Cole (Brassica Oleracea, CC, 2n=18) and Turnip (Brassica campestris, AA, 2n=20). Winter oilseed rape is sown during the last 10 days of August and the first ten days of September and harvested the following July, needing a temperate period for vernalization. The faster growing spring rapes are sown during late March and early April being harvested mid August to September. The main types of OSR grown at present are low and high erucic acid varieties. Double low (00) varieties contain low (typically less than 1%) levels of erucic acids (which humans find hard to digest), and low levels of glucosinolates (which makes the meal by-product indigestible for animals). Current uses for “00” varieties include oil for human consumption and high protein meal for animal feed. Industrial uses include feedstocks for pharmaceuticals and hydraulic oils. High erucic acid rape (HEAR) varieties are grown specifically for their erucic acid content—typically 50-60% of oil. The principal end use of HEAR is to produce erucamide, a “slip agent” used in polyethane manufacture. A small portion is used to produce behenyl alcohol, which is added to a waxy crude mineral oil to improve its flow.

Oilseed rape plants are bisexual and typically 60-70% self pollinated. The production of hybrids and introduction of genetic variation as a basis for selection was traditionally dependent on the adaptation of natural occurring phenomena such as self-incompatibility and cytoplasmic male sterility. Artificial pollination control methods such as manual emasculation or the use of gametocides are not widely applied in OSR breeding due to their limited practicability and high cost respectively.

Transgenic methods have been developed for the production of male or female-sterile plants, which provide interesting alternatives to the traditional techniques.

EP 0,344,029 describes a system for obtaining nuclear male sterility whereby plants are transformed with a male-sterility gene, which comprises, for example a DNA encoding a barnase under the control of a tapetum specific promoter, PTA29, which when incorporated into a plant ensures selective destruction of tapetum cells. Transformation of tobacco and oilseed rape plants with such a chimaeric gene resulted in plants in which pollen formation was completely prevented (Mariani et al. 1990, Nature 347: 737-741).

To restore fertility in the progeny of a male-sterile plant, a system was developed whereby the male-sterile plant is crossed with a transgenic plant carrying a fertility-restorer gene, which when expressed is capable of inhibiting or preventing the activity of the male-sterility gene (U.S. Pat. No. 5,689,041; U.S. Pat. No. 5,792,929). Such a fertility-restorer gene is placed under the control of a promoter directing expression at least in the cells in which the male-sterility gene is expressed. Mariani et al. (1992, Nature 357:384-387) demonstrated that the sterility encoded by the pTA29:bamase gene can be restored by the chimeric pTA29:barstar gene in oilseed rape.

Cytochemical and histochemical analysis of anther development of Brassica napus plants comprising the chimeric pTA29:barnase gene alone or with pTA29:barstar is described by De Block and De Brouwer (1993, Planta 189:218-225).

Successful transformation of Brassica species has been obtained by a number of methods including Agrobacterium infection (as described for example in EP 0,116,718 and EP 0,270,882), microprojectile bombardment (as described for example by Chen et al., 1994, Theor. Appl. Genet. 88:187-192) and direct DNA uptake (as described for example by De Block et al. 1989, Plant Physiol. 914:694-701; Poulsen 1996, Plant Breeding 115:209-225).

However, the foregoing documents fail to teach or suggest the present invention.

SUMMARY OF THE INVENTION

The invention relates to transgenic WOSR seed, or a plant that can be grown from such seed, the genomic DNA of which is characterized by one or both of the following characteristics:

a) the genomic DNA is capable of yielding at least two, preferably at least three, more preferably at least four, most preferably five of the sets of restriction fragments selected from the group of:

i) one set of two EcoRI fragments, one with a length of between 2140 and 2450 bp, preferably of about 2266 bp, and one with a length of more than 14 kbp;

ii) one set of two EcoRV fragments wherein one has a length of between 1159 and 1700 bp, preferably of about 1.4 kbp and the other has a length of more than 14 kbp;

iii) one set of two HpaI fragments, one with a length of between 1986 and 2140 bp, preferably with a length of about 1990 bp, and one with a length of between 2140 and 2450 bp, preferably of about 2229 bp;

iv) one set of three AflIII fragments, one with a length of between 514 and 805 bp, preferably with a length of about 522 bp, and one with a length of between 2140 and 2450 bp, preferably about 2250 bp, and one with a length of between 2450 and 2838 bp, preferably of about 2477 bp.;

v) one set of two NdeI fragments, both with a length of between 5077 and 14057 bp, preferably one of about 6500 bp, and one with a length of about 10 kbp;

wherein each of the restriction fragments is capable of hybridizing under standard stringency conditions, with the 3942 bp fragment comprising the PTA29-barnase sequence obtainable by HindIII digestion of the plasmid pTHW107 described herein; and/or

b) the genomic DNA is capable of yielding at least two, preferably at least three, more preferably four of the sets of restriction fragments selected from the group of:

i) one set of three BamHI fragments, wherein one has a length of between 805 and 1099 bp, preferably of about 814 bp, one has a length between 1700 and 1986 bp, preferably of about 1849 bp, one has a length between 2450 and 2838 bp, preferably of about 2607 bp, and one has a length between 5077 and 14057 bp, preferably of about 6500 bp;

ii) one set of four EcoRI fragments, one with a length of between 805 and 1159 bp, preferably of about 1094 bp, one with a length between 1986 and 2450 bp, preferably of about 2149 bp, and two with a length of between 5077 and 14057 bp, preferably one of about 7000 bp, and one with a length of about 10 kbp;

iii)one set of two EcoRV fragments wherein both have a length of between 5077 and 14057 bp, preferably one has a length of about 5.4 kbp and the other has a length of about 8 kbp;

iv) one set of three HindIII fragments, wherein one has a length of between 1700 and 2140 bp, preferably of about 1969 bp, and two have a length between 2450 and 2838 bp, preferably one has a length of about 2565 bp, and one has a length of about 2635 bp;

wherein each of the restriction fragments is capable of hybridizing under standard stringency conditions, with the 2182 bp fragment comprising the PTA29-barstar sequence obtainable by HpaI digestion of the plasmid pTHW118 described herein.

The present invention relates to a the seed of a WOSR plant, or a plant which can be grown from such seed, or cells, or tissues thereof, the genomic DNA of which is characterized by one or both of the following characteristics:

a) the genomic DNA is capable of yielding at least two, preferably at least three, for instance at least four, more preferably five of the sets of restriction fragments selected from the group described under a) above comprising the sets of restriction fragments described under a) i), ii), iii), iv), and v) above, whereby the selection can include any combination of i), ii), iii), iv), and v) described under a) above; and/or

b) the genomic DNA is capable of yielding at least two, preferably at least three, most preferably four of the sets of restriction fragments selected from the group described under b) above comprising the sets of restriction fragments described under b) i), ii), iii) and iv) above, whereby the selection can include any combination of i), ii), iii) and iv) described under b) above.

The invention further relates to WOSR seed, or plants grown from such seed, the genomic DNA of which is characterized by one or both of the following characteristics:

c) the genomic DNA can be used to amplify a DNA fragment of between 260 and 300 bp, preferably of about 280 bp, using a polymerase chain reaction with two primers having the nucleotide sequence of SEQ ID No 12 and SEQ ID No 19 respectively and/or

d) the genomic DNA can be used to amplify a DNA fragment of between 195 and 235 bp, preferably of about 215 bp, using a polymerase chain reaction with two primers having the nucleotide sequence of SEQ ID No 23 and SEQ ID No 41 respectively.

The invention further relates to WOSR seed, or plants grown from such seed, the genomic DNA of which is characterized by the characteristics described under a) and c) above and/or the characteristics described under b) and d) above.

The present invention relates to the seed of a WOSR plant, or a plant which can be grown from such seed, the genomic DNA of which is characterized by one or both of the following characteristics:

a) the genomic DNA is capable of yielding at least two, preferably at least three, more preferably at least four, most preferably five of the sets of restriction fragments selected from the group of:

i) One set of two EcoRI fragments, one with a length of between 2140 and 2450 bp, preferably of about 2266 bp, and one with a length of more than 14 kbp.

ii) one set of two EcoRV fragments wherein one has a length of between 1159 and 1700 bp, preferably of about 1.4 kbp and the other has a length of more than 14 kbp.

iii) one set of two HpaI fragments, one with a length of between 1986 and 2140 bp, preferably with a length of about 1990 bp, and one with a length of between 2140 and 2450 bp, preferably of about 2229 bp.

iv) one set of three AflIII fragments, one with a length of between 514 and 805 bp, preferably with a length of about 522 bp, one with a length of between 2140 and 2450 bp, preferably about 2250 bp, and one with a length of between 2450 and 2838 bp, preferably of about 2477 bp.

v) one set of two NdeI fragments, both with a length of between 5077 and 14057 bp, preferably one of about 6500 bp, and one with a length of about 10 kbp;

wherein each of the restriction fragments is capable of hybridizing under standard stringency conditions, with the 3942 bp fragment comprising the PTA29-barnase sequence obtainable by HindIII digestion of the plasmid pTHW107 described herein; and/or,

c) the genomic DNA can be used to amplify a DNA fragment of between 260 and 300 bp, preferably of about 280 bp, using a polymerase chain reaction with two primers having the nucleotide sequence of SEQ ID No 12 and SEQ ID No 19 respectively.

The present invention relates to a the seed of a WOSR plant, preferably a male-sterile plant, or a plant which can be grown from such seed, or cells, or tissues thereof, the genomic DNA of which is characterized in that it is capable of yielding at least two, preferably at least three, more preferably five of the sets of restriction fragments selected from the group described above comprising the sets of restriction fragments described under i), ii), iii), iv), and v) above, whereby the selection can include any combination of i), ii), iii), iv), and v) described above.

The present invention further relates to the seed of a WOSR plant, or a plant grown from such seed, the genomic DNA of which is characterized by one or both of the following characteristics:

b) the genomic DNA is capable of yielding at least two, preferably at least three, more preferably four of the restriction fragments or sets of restriction fragments selected from the group of:

i) one set of three BamHI fragments, wherein one has a length of between 805 and 1099 bp, preferably of about 814 bp, one has a length between 1700 and 1986 bp, preferably of about 1849 bp, one has a length between 2450 and 2838 bp, preferably of about 2607 bp, and one has a length between 5077 and 14057 bp, preferably of about 6500 bp;

ii) one set of four EcoRI fragments, one with a length of between 805 and 1159 bp, preferably of about 1094 bp, one with a length between 1986 and 2450 bp, preferably of about 2149 bp, and two with a length of between 5077 and 14057 bp, preferably one of about 7000 bp, and one with a length of about 10 kbp;

iii) one set of two EcoRV fragments wherein both have a length of between 5077 and 14057 bp, preferably one has a length of about 5.4 kbp and the other has a length of about 8 kbp;

iv) one set of three HindIII fragments, wherein one has a length of between 1700 and 2140 bp, preferably of about 1969 bp, and two have a length between 2450 and 2838 bp, preferably one has a length of about 2565 bp, and one has a length of about 2635 bp;

wherein each of the restriction fragments is capable of hybridizing under standard stringency conditions, with the 2182 bp fragment comprising the PTA29-barstar sequence obtainable by HpaI digestion of the plasmid pTHW118 described herein;

and/or

d) the genomic DNA can be used to amplify a DNA fragment of between 195 and 235 bp, preferably of about 215 bp, using a polymerase chain reaction with two primers having the nucleotide sequence of SEQ ID No 23 and SEQ ID No 41 respectively.

The present invention relates to the seed of a WOSR plant, preferably a fertility restorer plant, or a plant which can be grown from such seed, or cells, or tissues thereof, the genomic DNA of which is capable of yielding at least two, preferably at least three, most preferably four of the sets of restriction fragments selected from the group described above comprising the sets of restriction fragments described under b) i), ii), iii) and iv) above, whereby the selection can include any combination of i), ii), iii) and iv) described above.

The present invention relates to transgenic WOSR plants, cells, tissues or seeds which are preferably characterized by one or both of the characteristics described under b) and/or d) above, respectively, or alternatively, additionally characterized by one or both of the characteristics described under a) and c) above.

The invention further relates to transgenic, preferably hybrid fertility restored WOSR plants, cells, tissues or seeds obtained from the crossing of the male-sterile plant with the fertility restorer plant of the invention characterized by the respective characteristics described above, whereby the fertility restored plants, cells tissues or seeds are characterized by both the molecular characteristics of the male-sterile and those of the fertility restorer WOSR plant described above. The invention further relates to transgenic, preferably hybrid WOSR plants, cells, tissues or seeds obtained from the crossing of the male-sterile plant with the fertility restorer plant of the invention characterized by the molecular characteristics described above, whereby the hybrid plants, cells tissues or seeds are characterized by the molecular characteristics of the fertility restorer WOSR plant described above.

The invention also relates to the seed deposited at the ATCC under accession number PTA-730, a plant which is grown from this seed, and cells or tissues from a plant grown from this seed. The invention further relates to plants obtainable by propagation of, and/or breeding with a WOSR plant grown from the seed deposited at the ATCC under accession number PTA-730.

The invention further relates to a process for producing hybrid WOSR seed, which comprises, crossing the male-sterile WOSR plant of the present invention with the fertility-restorer WOSR plant of the invention.

The invention further relates to a WOSR plant, plant cell, plant tissue or seed, which comprises a foreign DNA comprising at least one transgene, integrated into a part of the chromosomal DNA characterized by the sequence of SEQ ID No 22 and/or a foreign DNA comprising at least one transgene, integrated into a part of the chromosomal DNA characterized by the sequence of SEQ ID No 34.

The invention further provides a process for producing a transgenic cell of a WOSR plant or a plant obtained therefrom, which comprises inserting a recombinant DNA molecule into a part of the chromosomal DNA of an WOSR cell characterized by the sequence of SEQ ID No 22 and, optionally, regenerating a WOSR plant from the transformed WOSR cell.

The invention further provides a process for producing a transgenic cell of a WOSR plant or a plant obtained therefrom, which comprises inserting a recombinant DNA molecule into a part of the chromosomal DNA of an WOSR cell characterized by the sequence of SEQ ID No 34 and, optionally, regenerating a WOSR plant from the transformed WOSR cell.

The invention further relates to a method for identifying a transgenic plant, or cells or tissues thereof, comprising the elite event MS-BN1 of the invention, which method comprises establishing one or both of the following characteristics of the genomic DNA of the transgenic plant, or its cells or tissues:

a) the genomic DNA is capable of yielding at least two, preferably at least three, more preferably at least four, most preferably five of the sets of restriction fragments selected from the group of:

i) one set of two EcoRI fragments, one with a length of between 2140 and 2450 bp, preferably of about 2266 bp, and one with a length of more than 14 kbp;

ii) one set of two EcoRV fragments wherein one has a length of between 1159 and 1700 bp, preferably of about 1.4 kbp and the other has a length of more than 14 kbp;

iii) one set of two HpaI fragments, one with a length of between 1986 and 2140 bp, preferably with a length of about 1990 bp, and one with a length of between 2140 and 2450 bp, preferably of about 2229 bp;

iv) one set of three AflIII fragments, one with a length of between 514 and 805 bp, preferably with a length of about 522 bp, one with a length of between 2140 and 2450 bp, preferably about 2250 bp, and one with a length of between 2450 and 2838 bp, preferably of about 2477 bp.;

v) one set of two NdeI fragments, both with a length of between 5077 and 14057 bp, preferably one of about 6500 bp, and one with a length of about 10 kbp;

wherein each of the restriction fragments is capable of hybridizing under standard stringency conditions, with the 3942 bp fragment comprising the PTA29-barnase sequence obtainable by HindIII digestion of the plasmid pTHW107 described herein; and/or

c) the genomic DNA can be used to amplify a DNA fragment of between 260 and 300 bp, preferably of about 280 bp, according to the PCR Identification Protocol described herein with two primers identifying the elite event having the nucleotide sequence of SEQ ID No 12 and SEQ ID No 19 respectively.

The invention further relates to a method for identifying a transgenic plant, or cells or tissues thereof, comprising the elite event RF-BN1 of the invention, which method comprises establishing one or both of the following characteristics of the genomic DNA of the transgenic plant, or its cells or tissues:

b) the genomic DNA is capable of yielding at least two, preferably at least three, more preferably four of the restriction fragments or sets of restriction fragments selected from the group of:

one set of three BamHI fragments, wherein one has a length of between 805 and 1099 bp, preferably of about 814 bp, one has a length between 1700 and 1986 bp, preferably of about 1849 bp, one has a length between 2450 and 2838 bp, preferably of about 2607 bp, and one has a length between 5077 and 14057 bp, preferably of about 6500 bp;

one set of four EcoRI fragments, one with a length of between 805 and 1159 bp, preferably of about 1094 bp, one with a length between 1986 and 2450 bp, preferably of about 2149 bp, and two with a length of between 5077 and 14057 bp, preferably one of about 7000 bp, and one with a length of about 10 kbp;

one set of two EcoRV fragments wherein both have a length of between 5077 and 14057 bp, preferably one has a length of about 5.4 kbp and the other has a length of about 8 kbp;

one set of three HindIII fragments, wherein one has a length of between 1700 and 2140 bp, preferably of about 1969 bp, and two have a length between 2450 and 2838 bp, preferably one has a length of about 2565 bp, and one has a length of about 2635 bp;

wherein each of the restriction fragments is capable of hybridizing under standard stringency conditions, with the 2182 bp fragment comprising the PTA29-barstar sequence obtainable by HpaI digestion of the plasmid pTHW118 described herein, and/or

d) the genomic DNA can be used to amplify a DNA fragment of between 195 and 235 bp, preferably of about 215 bp, using the PCR identification protocol described herein with two primers identifying the elite event having the nucleotide sequence of SEQ ID No 23 and SEQ ID No 41 respectively.

The invention further relates to a kit for identifying the plants comprising elite event RF-BN1 of the present invention, said kit comprising PCR probes recognizing the T-DNA and the 3′ or 5′ flanking sequence of RF-BN, preferably having the nucleotide sequence of SEQ ID No. 23 and SEQ ID No. 41, respectively.

BRIEF DESCRIPTION OF THE DRAWINGS

The following detailed description, given by way of example, but not intended to limit the invention to specific embodiments described, may be understood in conjunction with the accompanying Figures, incorporated herein by reference, in which:

FIG. 1. Plasmid map of pVE113

FIG. 2. Restriction map obtained after digestion of MS-BN1 genomic DNA. Loading sequence of the gel analyzed by Southern blot: lane 1, MS-BN1 DNA digested with EcoRI, lane 2, MS-BN1 DNA digested with EcoRV, lane 3, MS-BN1 DNA digested with HpaI, lane 4, MS-BN1 DNA digested with AflIII, lane 5, MS-BN1 DNA digested with NdeI, lane 6, non-transgenic WOSR DNA digested with BamHI, lane 7, non-transgenic WOSR digested with BamHI+control plasmid pTHW107 DNA digested with BamHI.

FIG. 3. Restriction map obtained after digestion of RF-BN1 genomic DNA. Loading sequence of the gel analyzed by Southern blot: lane 1, RF-MS1 DNA digested with BamHI, lane 2, RF-BN1 DNA digested with EcoRI, lane 3, RF-BN1 DNA digested with EcoRV, lane 4, RF-BN1 DNA digested with HindIII, lane 5, non-transgenic WOSR DNA digested with BamHI, lane 6, non-transgenic WOSR digested with BamHI+control plasmid pTHW118 DNA digested with BamHI.

FIG. 4. PCR analysis of different lines using the MS-BN1 PCR identification protocol. Loading sequence of the gel: lane 1, DNA sample from an OSR plant comprising the transgenic event MS-BN1, lane 2, DNA sample from an OSR plant comprising another transgenic event, lane 3, DNA from wild-type OSR, lane 4, negative control (water), lane 5, molecular weight marker (100 bp ladder).

FIG. 5. PCR analysis of different lines using the RF-BN1 PCR identification protocol. Loading sequence of the gel: lane 1, DNA sample from an OSR plant comprising the transgenic event RF-BN1, lane 2, DNA sample from an OSR plant comprising another transgenic event, lane 3, DNA from wild-type OSR, lane 4, negative control (water), lane 5, molecular weight marker (100 bp ladder).

DETAILED DESCRIPTION

The term “gene” as used herein refers to any DNA sequence comprising several operably linked DNA fragments such as a promoter and a 5′ untranslated region (the 5′UTR), which together form the promoter region, a coding region (which may or may not code for a protein), and an untranslated 3′ region (3′UTR) comprising a polyadenylation site. Typically in plant cells, the 5′UTR, the coding region and the 3′UTR are transcribed into a RNA which, in the case of a protein encoding gene, is translated into the protein. A gene may include additional DNA fragments such as, for example, introns. As used herein, a genetic locus is the position of a given gene in the genome of a plant. The term “chimeric” when referring to a gene or DNA sequence is used to indicate that the gene or DNA sequence comprises at least two functionally relevant DNA fragments (such as promoter, 5′UTR, coding region, 3′UTR, intron) that are not naturally associated with each other and originate, for example, from different sources. “Foreign” referring to a gene or a DNA sequence with respect to a plant species is used to indicate that the gene or DNA sequence is not naturally found in that plant species, or is not naturally found in that genetic locus in that plant species. The term “foreign DNA” will be used herein to refer to a DNA sequence as it has incorporated into the genome of a plant as a result of transformation. The “transforming DNA” as used herein refers to a recombinant DNA molecule used for transformation. The transforming DNA usually comprises at least one “gene of interest” (e.g. a chimeric gene) which is capable of conferring one or more specific characteristics to the transformed plant. The term “recombinant DNA molecule” is used to exemplify and thus can include an isolated nucleic acid molecule which can be DNA and which can be obtained through recombinant or other procedures.

As used herein the term “transgene” refers to a gene of interest as incorporated in the genome of a plant. A “transgenic plant” refers to a plant comprising at least one transgene in the genome of all of its cells.

The foreign DNA present in the plants of the present invention will preferably comprise two genes of interest, more specifically, either a male-sterility gene and a herbicide resistance gene or a fertility restorer gene and a herbicide resistance gene.

A “male-sterility gene” as used herein refers to a gene which upon expression in the plant renders the plant incapable of producing fertile, viable pollen. An example of a male sterility gene is a gene comprising a DNA sequence encoding barnase, under the control of a promoter directing expression in tapetum cells. More specifically, according to the present invention the male-sterility gene is “TA29-barnase” as described herein.

A “fertility restorer gene” as used herein refers to a gene which upon expression in a plant comprising a male-sterility gene, is capable of preventing phenotypic expression of the male-sterility gene, restoring fertility in the plant. More specifically the fertility restorer gene will comprise a DNA encoding a protein or polypeptide capable of preventing phenotypic expression of the male-sterility gene, under the control of a promoter directing expression in at least the cells in which the male-sterility DNA is expressed. More specifically, according to the present invention, the fertility restorer gene is “TA29-barstar” as described herein.

The incorporation of a recombinant DNA molecule in the plant genome typically results from transformation of a cell or tissue (or from another genetic manipulation). The particular site of incorporation is either due to chance or is at a predetermined location (if a process of targeted integration is used).

The foreign DNA can be characterized by the location and the configuration at the site of incorporation of the recombinant DNA molecule in the plant genome. The site in the plant genome where a recombinant DNA has been inserted is also referred to as the “insertion site” or “target site”. Insertion of the transgene into the plant genome can be associated with a deletion of plant DNA, referred to as “target site deletion”. A “flanking region” or “flanking sequence” as used herein refers to a sequence of at least 20 bp, preferably at least 50 bp, and up to 5000 bp of the plant genome which is located either immediately upstream of and contiguous with or immediately downstream of and contiguous with the foreign DNA. Transformation procedures leading to random integration of the foreign DNA will result in transformants with different flanking regions, which are characteristic and unique for each transformant. When the transgene is introduced into a plant through traditional crossing, its insertion site in the plant genome, or its flanking regions will generally not be changed. An “insertion region” as used herein refers to the region corresponding to the region of at least 40 bp, preferably at least 100 bp, and up to more than 10000 bp, encompassed by the upstream and the downstream flanking regions of a transgene in the (untransformed) plant genome and including the insertion site (and possible target site deletion). Taking into consideration minor differences due to mutations within a species, an insertion region will retain at least 85%, preferably 90%, more preferably 95%, and most preferably 100% sequence identity with the sequence comprising the upstream and downstream flanking regions of the foreign DNA in a given plant of that species.

Expression of a gene of interest refers to the fact that the gene confers on the plant one or more phenotypic traits (e.g. herbicide tolerance) that were intended to be conferred by the introduction of the recombinant DNA molecule—the transforming DNA—used during transformation (on the basis of the structure and function of part or all of the gene(s) of interest).

An “event” is defined as a (artificial) genetic locus that, as a result of genetic manipulation, carries a foreign DNA comprising at least one copy of the gene(s) of interest. The typical allelic states of an event are the presence or absence of the foreign DNA. As used herein an “MS” event and an “RF” event will refer to events carrying the “TA29-bamase” and “TA29-barstar” transgenes respectively. An event is characterized phenotypically by the expression of one or more transgene. At the genetic level, an event is part of the genetic makeup of a plant. At the molecular level, an event is characterized by the restriction map (e.g. as determined by Southern blotting) and/or by the upstream and/or downstream flanking sequences of the transgene, and/or the molecular configuration of the transgene. Usually transformation of a plant with a transforming DNA comprising at least one gene of interest leads to a multitude of events, each of which is unique.

An “elite event”, as used herein, is an event which is selected from a group of events, obtained by transformation with the same transforming DNA or by back-crossing with plants obtained by such transformation, based on the expression and stability of the transgene and its compatibility with optimal agronomic characteristics of the plant comprising it. Thus the criteria for elite event selection are one or more, preferably two or more, advantageously all of the following:

a) That the presence of the transgene does not compromise other desired characteristics of the plant, such as those relating to agronomic performance or commercial value;

b) That the event is characterized by a well defined molecular configuration which is stably inherited and for which appropriate diagnostic tools for identity control can be developed;

c) That the gene(s) of interest in the transgene show(s) a correct, appropriate and stable spatial and temporal phenotypic expression, both in heterozygous (or hemizygous) and homozygous condition of the event, at a commercially acceptable level in a range of environmental conditions in which the plants carrying the event are likely to be exposed in normal agronomic use;

It is preferred that the foreign DNA is associated with a position in the plant genome that allows introgression into desired commercial genetic backgrounds.

The status of an event as an elite event is confirmed by introgression of the elite event in different relevant genetic backgrounds and observing compliance with one, two or all of the criteria e.g. a), b) and c) above.

Additionally, for the transgenes encoding male sterility and fertility restoration described herein, selection of the elite events will also be determined on the compatibility between these events, more specifically that the progeny resulting from a cross between a plant carrying a male-sterility event and a plant carrying a fertility restorer event, in which both events are present have the following characteristics:

a) adequate phenotypic expression of the fertility restored phenotype, i.e. male fertility; and

b) phenotypic expression at a commercially acceptable level in a range of environmental conditions in which plants carrying the two events are likely to be exposed in normal agronomic use;

An “elite event” thus refers to a genetic locus comprising a transgene, which answers to the above-described criteria. A plant, plant material or progeny such as seeds can comprise one or more elite events in its genome.

The “diagnostic tools” developed to identify an elite event or the plant or plant material comprising an elite event, are based on the specific genomic characteristics of the elite event, such as, a specific restriction map of the genomic region comprising the foreign DNA and/or the sequence of the flanking region(s) of the transgene. A “restriction map” as used herein refers to a set of Southern blot patterns obtained after cleaving plant genomic DNA with a particular restriction enzyme, or set of restriction enzymes and hybridization with a probe sharing sequence similarity with the transgene under standard stringency conditions. Standard stringency conditions as used herein refers to the conditions for hybridization described herein or to the conventional hybridizing conditions as described by Sambrook et al. (1989) (Molecular Cloning: A Laboratory Manual, Second Edition, Cold Spring Harbour Laboratory Press, N.Y.) which for instance can comprise the following steps: 1) immobilizing plant genomic DNA fragments on a filter, 2) prehybridizing the filter for 1 to 2 hours at 42° C. in 50% formamide, 5×SSPE, 2×Denhardt's reagent and 0.1% SDS, or for 1 to 2 hours at 68° C. in 6×SSC, 2×Denhardt's reagent and 0.1% SDS, 3) adding the hybridization probe which has been labeled, 4) incubating for 16 to 24 hours, 5) washing the filter for 20 min. at room temperature in 1×SSC, 0.1%SDS, 6) washing the filter three times for 20 min. each at 68° C. in 0.2×SSC, 0.1%SDS, and 7) exposing the filter for 24 to 48 hours to X-ray film at −70° C. with an intensifying screen.

Due to the (endogenous) restriction sites present in a plant genome prior to incorporation of the foreign DNA, insertion of a foreign DNA will alter the specific restriction map of that genome. Thus, a particular transformant or progeny derived thereof can be identified by one or more specific restriction patterns. The conditions for determining the restriction map of an event are laid out in a “restriction map identification protocol”. Alternatively, plants or plant material comprising an elite event can be identified by testing according to a PCR identification protocol. This is a PCR using primers which specifically recognize the elite event. Essentially, a set of primers is developed which recognizes a) a sequence within the 3′ or 5′ flanking sequence of the elite event and b) a sequence within the foreign DNA, which primers amplify a fragment (integration fragment) preferably of between 100 and 350 nucleotides. Preferably, a control is included of a set of primers which amplifies a fragment within a housekeeping gene of the plant species (preferably a fragment which is larger than the amplified integration fragment). The optimal conditions for the PCR, including the sequence of the specific primers is specified in a PCR identification protocol.

The present invention relates to the development of a set of elite events in WOSR, MS-BN1 and RF-BN1, to the plants comprising these events, the progeny obtained from the crossing of these plants and to the plant cells, or plant material derived from these events. Plants comprising elite event MS-BN1 were obtained through transformation with pTHW107 as described in example 1. Plants comprising elite event RF-BN1 were obtained through transformation with pTHW118, also described in example 1.

The recombinant DNA molecule used for generation of elite event MS-BN1 comprises a DNA sequence encoding a barnase molecule, under the control of a promoter directing expression selectively in tapetum cells (termed “TA29-barnase”). The TA29 promoter has a “tapetum selective” expression pattern in OSR (De Block and Debrouwer, Planta 189:218-225, 1993). The expression of the TA29-barnase gene in WOSR plants results in destruction of the tapetum rendering the plants male-sterile (Mariani et al, 1990, above).

The recombinant DNA molecule used for generation of elite event RF-BN1 comprises a DNA sequence encoding a barstar molecule, wherein the under the control of a tapetum specific promoter (termed “PTA29-barstar”). The expression of the TA29-barstar gene in WOSR plants will, in the presence of a “TA29-barnase” gene in the plant prevent the activity of bamase in the tapetum cells of the plant, preventing the destruction of the tapetum and thus restoring fertility in these plants (Mariani et al. 1992, above).

The recombinant DNAs used for the generation of elite event MS-BN1 and RF-BN1 both additionally comprise a DNA sequence encoding the enzyme phosphinothricin acetyl transferase and the 35S promoter of Cauliflower Mosaic Virus, wherein the sequence encoding phosphinothricin acetyl transferase is under the control of the 35S promoter (termed “35S-bar”). The 35S promoter has a “constitutive” expression pattern in OSR, which means that it is significantly expressed in most cell types, during most of the plant life cycle. The expression of the 35S-bar gene in OSR plants confers resistance to herbicidal compounds phosphinothricin or bialaphos or glufosinate, or more generally, glutaminc synthetase inhibitors, or salts or optical isomers thereof.

WOSR Plants or plant material comprising MS-BN1 can be identified according to the restriction map identification protocol described for MS-BN1 in Example 5 herein. Briefly, WOSR genomic DNA is digested with a selection (preferably two to five) of the following restriction enzymes: EcoRI, EcoRV, NdeI, HpaI, AflIII, is then transferred to nylon membranes and hybridized with the 3942 bp HindIII fragment of plasmid pTHW107 (or of the T-DNA comprised therein). It is then determined for each restriction enzyme used whether the following fragments can be identified:

EcoRI: one fragment of between 2140 and 2450 bp, preferably of about 2266 bp, and one fragment of more than 14 kbp;

EcoRV: one fragment of between 1159 and 1700 bp, preferably of about 1,4 kbp and one fragment of more than 14 kbp;

HpaI: one fragment of between 1986 and 2140 bp, preferably of about 1990 bp, and one fragment of between 2140 and 2450 bp, preferably of about 2229 bp;

AflIII: one fragment of between 514 and 805 bp, preferably of about 522 bp, one fragment of between 2140 and 2450 bp, preferably of about 2250 bp, and one fragment of between 2450 and 2838 bp, preferably of about 2477 bp;

NdeI: two fragments with a length of between 5077 and 14057 bp, preferably one of about 6500 bp, and one with a length of about 10 kbp;

The lengths of the DNA fragments are determined by comparison with a set of DNA fragments of known length, particularly the PstI fragments of phage lambda DNA. A fragment of more than 14 kbp is estimated to have a length between 14 kbp and 40 kbp, when extraction of the DNA occurs according to the method of Dellaporta et al. (1983, Plant Molecular Biology Reporter, 1, vol. 3, p. 19-21).

If the plant material after digestion with at least two, preferably at least three, particularly with at least four, more particularly with all of these restriction enzymes, yields DNA fragments with the same length as those described above, the WOSR plant is determined to harbor elite event MS-BN1.

Plants or plant material comprising MS-BN1 can also be identified according to the PCR identification protocol described for MS-BN1 in Example 5 herein. Briefly, WOSR genomic DNA is amplified by PCR using a primer which specifically recognizes a flanking sequence of MS-BN1, preferably recognizing the 5′ or 3′ flanking sequence of MS-BN1 described herein, particularly the primer with the sequence of SEQ ID No 19, and a primer which recognizes a sequence in the transgene, particularly the primer with the sequence of SEQ ID No 12. Endogenous WOSR primers are used as controls. If the plant material yields a fragment of between 260 and 300 bp, preferably of about 280 bp, the WOSR plant is determined to harbor elite event MS-BN1.

Plants harboring MS-BN1 are, in the absence of a restorer gene in their genome, phenotypically characterized by the fact that they are male sterile. A male sterile plant is defined as not being able to produce fertile, viable pollen.

Plants harboring MS-BN1 can, for example, be obtained from seeds comprising MS-BN1 deposited at the ATCC under accession number PTA-730. Such plants can be further propagated to introduce the elite event of the invention into other cultivars of the same plant species.

WOSR Plants or plant material comprising RF-BN1 can be identified according to the restriction map identification protocol described for RF-BN1 in Example 5 herein. Briefly, WOSR genomic DNA is digested with a selection (preferably two to four) of the following restriction enzymes: BamHI, EcoRI, EcoRV, and HindIII, is then transferred to nylon membranes and hybridized with the 2182 bp HpaI fragment of plasmid pTHW118 (or of the T-DNA comprised therein). It is then determined for each restriction enzyme used whether the following fragments can be identified:

BamHI: one fragment of between 805 and 1099 bp, preferably of about 814 bp, one fragment of between 1700 and 1986 bp, preferably of about 1849 bp, one fragment of between 2450 and 2838 bp, preferably of about 2607 bp, and one fragment of between 5077 and 14057 bp, preferably of about 6500 bp;

EcoRI: one fragment of between 805 and 1159 bp, preferably of about 1094 bp, one fragment of between 1986 and 2450 bp, preferably of about 2149 bp, and two fragments of between 5077 and 14057 bp, preferably one of about 7000 bp, and one of about 10 kbp;

EcoRV: two fragments of between 5077 and 14057 bp, preferably one of about 5.4 kbp and of about 8 kbp;

HindIII: one fragment of between 1700 and 1986 bp, preferably of about 1969 bp, and two fragments of between 2450 and 2838 bp, preferably one of about 2565 bp, and one of about 2635 bp;

The lengths of the DNA fragments are determined by comparison with a set of DNA fragments of known length, particularly the PstI fragments of phage lambda DNA. If the plant material after digestion with at least two, preferably at least 3, more particularly with all of these restriction enzymes, yields DNA fragments with the same length as those described above, the WOSR plant is determined to harbor elite event RF-BN1.

Plants or plant material comprising RF-BN1 can also be identified according to the PCR identification protocol described for RF-BN1 in Example 5 herein. Briefly, WOSR genomic DNA is amplified by PCR using a primer which specifically recognizes a flanking sequence of RF-BN1, preferably the 5′ or 3′ flanking sequence of RF-BN1 described herein, particularly the primer with the sequence of SEQ ID No 41, and a primer which recognizes a sequence in the transgene, particularly the primer with the sequence of SEQ ID No 23. Endogenous WOSR primers are used as controls. If the plant material yields a fragment of between 195 and 235 bp, preferably of about 215 bp, the WOSR plant is determined to harbor elite event RF-BN1.

Plants harboring RF-BN1 are characterized by the fact that barstar is expressed in the cells of the tapetum. The production of barstar in the tapetum cells of the plant has been shown to be neither beneficial nor detrimental to the production of pollen (Mariani et al. 1992, above). Thus, in the absence of a male sterility gene in the genome of the plant, the TA29-barstar gene will not result in an observable phenotype. In the presence of a male-sterility gene in the genome of the plant, the TA29-barstar gene will result in a fertility restored i.e., fertile phenotype. A plant with a fertility restored phenotype is defined as a plant which, despite the presence of a male sterility gene in its genome, is capable of producing fertile, viable pollen.

Plants harboring RF-BN1 can, for example, be obtained from seeds deposited at the ATCC under accession number PTA-730. Such plants can be further propagated and/or used in a conventional breeding scheme to introduce the elite event of the invention into other cultivars of the same plant species.

Plants harboring MS-BN1 and/or RF-BN1 are also characterized by their glufosinate tolerance, which in the context of the present invention includes that plants are tolerant to the herbicide Liberty™. Tolerance to Liberty™ is defined by the criterium that spraying of the plants in the three to four leaf stage (3V to 4V) with at least 200 grams active ingredient/hectare (g.a.i./ha), preferably 400 g.a.i./ha, and possibly up to 1600 g.a.i./ha, does not kill the plants. Plants harboring MS-BN1 and/or RF-BN1 can further be characterized by the presence in their cells of phosphinothricin acetyl transferase as determined by a PAT assay (De Block et al, 1987, supra).

The WOSR plants of this invention can be cultivated in a conventional way. The presence of the 35S-bar gene ensures that they are tolerant to glufosinate. Therefore, weeds in the fields where such WOSR plants are grown can be controlled by application of herbicides comprising glufosinate as an active ingredient (such as Liberty™).

Plants harboring MS-BN1 and/or RF-BN1 are also characterized by having agronomical characteristics which are comparable to commercially available WOSR varieties in the US. The agronomical characteristics of relevance are: plant height, strength/stiffness of straw, tendency to lodge, winter-hardiness, shatter resistance, drought tolerance, disease resistance (Black leg, Light leafspot, Sclerotinia) and grain production and yield.

It has been observed that the presence of the foreign DNA in the insertion regions of the Brassica napus WOSR plant genome described herein, more particularly at these insertion sites in the Brassica napus WOSR plant genome, confers particularly interesting phenotypic and molecular characteristics to the plants comprising these events. More specifically, the presence of the foreign DNA in these particular regions in the genome of these plants results in stable phenotypic expression of the transgenes without significantly compromising any aspect of desired agronomic performance of the plants, making them particularly suited for the production of hybrid WOSR. Thus, the insertion regions, corresponding to SEQ ID No 22 and SEQ ID No 34, more particularly the insertion site of MS-BN1 and RF-BN1 therein, is shown to be particularly suited for the introduction of one or more gene(s) of interest. More particularly, the insertion regions of MS-BN1 (SEQ ID No 22) and of RF-BN1 (SEQ ID No 34), or the insertion sites of MS-BN1 and RF-BN1 respectively therein, are particularly suited for the introduction of plasmids comprising a male-sterility gene and a fertility restorer gene respectively ensuring optimal expression of each of these genes or of both genes in a plant without compromising agronomic performance.

A recombinant DNA molecule can be specifically inserted in an insertion region by targeted insertion methods. Such methods are well known to those skilled in the art and comprise, for example, homologous recombination using a recombinase such as, but not limited to either FLP recombinase from Saccharomyces cervisiae (U.S. Pat. No. 5,527,695), the CRE recombinase from Escherichia coli phage P1 (published PCT application WO 9109957, the recombinase from pSRI of Saccharomyces rouxii (Araki et al. 1985, J Mol Biol 182:191-203), or the lambda phage recombination system such as described in U.S. Pat. No. 4,673,640.

As used herein, “sequence identity” with regard to nucleotide sequences (DNA or RNA), refers to the number of positions with identical nucleotides divided by the number of nucleotides in the shorter of the two sequences. The alignment of the two nucleotide sequences is performed by the Wilbur and Lipmann algorithm (Wilbur and Lipmann, 1983) using a window-size of 20 nucleotides, a word length of 4 nucleotides, and a gap penalty of 4. Computer-assisted analysis and interpretation of sequence data, including sequence alignment as described above, can, e.g., be conveniently performed using the programs of the Intelligenetics™ Suite (Intelligenetics Inc., Cafil.). Sequences are indicated as “essentially similar” when such sequence have a sequence identity of at least about 75%, particularly at least about 80%, more particularly at least about 85%, quite particularly about 90%, especially about 95%, more especially about 100%, quite especially are identical. It is clear than when RNA sequences are said to be essentially similar or have a certain degree of sequence identity with DNA sequences, thymine (T) in the DNA sequence is considered equal to uracil (U) in the RNA sequence.

As used herein “comprising” is to be interpreted as specifying the presence of the stated features, integers, steps or components as referred to, but does not preclude the presence or addition of one or more features, integers, steps or components, or groups thereof. Thus, e.g., a nucleic acid or protein comprising a sequence of nucleotides or amino acids, may comprise more nucleotides or amino acids than the actually cited ones, i.e., be embedded in a larger nucleic acid or protein. A chimeric gene comprising a DNA sequence which is functionally or structurally defined, may comprise additional DNA sequences, etc.

The following examples describe the development and characteristics of WOSR plants harboring the elite events MS-BN1 and RF-BN1.

Unless otherwise stated, all recombinant DNA techniques are carried out according to standard protocols as described in Sambrook et al. (1989) Molecular Cloning: A Laboratory Manual, Second Edition, Cold Spring Harbour Laboratory Press, N.Y. and in Volumes 1 and 2 of Ausubel et al. (1994) Current Protocols in Molecular Biology, Current Protocols, USA. Standard materials and methods for plant molecular work are described in Plant Molecular Biology Labfax (1993) by R. D. D. Croy published by BIOS Scientific Publications Ltd (UK) and Blackwell Scientific Publications, UK.

In the description and examples, reference is made to the following sequences:

SEQ ID No 1: plasmid pTHW107

SEQ ID No 2: plasmid pTHW118

SEQ ID No 3: primer 248

SEQ ID No 4: primer 249

SEQ ID No 5: primer 247

SEQ ID No 6: primer 250

SEQ ID No 7: primer 251

SEQ ID No 8: primer 254

SEQ ID No 9: primer 258

SEQ ID No 10: primer SP6

SEQ ID No 11: primer T7

SEQ ID No 12: primer 201 (BNA01)

SEQ ID No 13: sequence comprising the 5′ flanking region MS-BN1

SEQ ID No 14: primer 611

SEQ ID No 15: primer 259

SEQ ID No 16: primer 260

SEQ ID No 17: primer 24

SEQ ID No 18: sequence comprising the 3′ flanking region MS-BN1

SEQ ID No 19: primer 51 (BNA02)

SEQ ID No 20: primer 48

SEQ ID No 21: sequence comprising the target site deletion of MS-BN1

SEQ ID No 22: insertion region MS-BN1

SEQ ID No 23: primer 193 (BNA03)

SEQ ID No 24: sequence comprising the 5′ flanking region RF-BN1

SEQ ID No 25: primer 286

SEQ ID No 26: primer 314

SEQ ID No 27: primer 315

SEQ ID No 28: primer 316

SEQ ID No 29: primer 288

SEQ ID No 30: sequence comprising the 3′ flanking region RF-BN1

SEQ ID No 31: primer 269

SEQ ID No 32: primer 283

SEQ ID No 33: primer 284

SEQ ID No 34: insertion region RF-BN1

SEQ ID No 35: primer 57

SEQ ID No 36: sequence comprising the 5′ flanking region MS-BN1 WOSR

SEQ ID No 37: primer 68

SEQ ID No 38: sequence comprising the 3′ flanking region MS-BN1 WOSR

SEQ ID No 39: sequence comprising the 5′ flanking region RF-BN1 WOSR

SEQ ID No 40: sequence comprising the 3′ flanking region RF-BN1 WOSR

SEQ ID No 41: primer 268 (BNA04)

SEQ ID No 42: primer BNA05

SEQ ID No 43: primer BNA06

EXAMPLES Example 1 Transformation of Brassica Napus with a Male-sterility Gene and a Restorer Gene

1.1. Construction of the Chimeric DNA Comprising the Barnase Gene under the Control of a Tapetum Specific Promoter (pTHW107).

Plasmid pTHW107 was essentially derived from the intermediate vector pGSV1. PGSV1 is itself derived from pGSC1700 (Cornelissen and Vandewielle, 1989), but comprises an artificial T-region consisting of the left and right border sequences of the T-DNA form pTiB6S3 and multilinker cloning sites allowing the insertion of chimeric genes between the T-DNA border repeats. The pGSV1 vector is provided with a barstar gene on the plasmid mainframe, with regulatory signals for expression in E. coli.

A full description of the T-DNA comprised between the border repeats of pTHW107 (SEQ ID No. 1) is given in Table 1:

TABLE 1 T-DNA of plasmid pTHW107 nt positions Orientation Description and references  1-25 Right border repeat from the TL-DNA from pTiB6S3 (Gielen et al (1984) The EMBO Journal 3: 835-846). 26-97 Synthetic polylinker derived sequences 309-98  Counter The 3′untranslated end from the TL-DNA gene 7 (3′g7) of pTiB6S3 clockwise (Velten and Schell. (1985) Nucleic Acids Research 13: 6981-6998; Dhaese et al. (1983) The EMBO Journal 3: 835-846). 310-330 Synthetic polylinker derived sequences 882-331 Counter The coding sequence of the bar gene of Streptomyces clockwise hygroscopicus (Thompson et al. (1987) The EMBO Journal 6: 2519-2523). The N-terminal two codons of the wild type bar coding region have been substituted for the codons ATG and GAC respectively. 2608-883  Counter The promoter from the atS1A ribulose-1,5-biphosphate carboxylase clockwise small subunit gene from Arabidopsis thaliana (PssuAra) (Krebbers et al. (1988) Plant Molecular Biology 11: 745-759). 2609-2658 Synthetic polylinker derived sequences 2919-2659 Counter A 260 bp TaqI fragment from the 3′ untranslated end of the clockwise nopaline synthase gene (3′nos) from the T-DNA of pTiT37 and containing plant polyadenylation signals (Depicker et al. (1982) Journal of Molecular and Applied Genetics 1: 561-573). 2920-3031 3′untranslated region downstream from the barnase coding sequence of B. amyloliquefaciens 3367-3032 Counter The coding region of the barnase gene from Bacillus clockwise amyloliquefaciens (Hartley (1988) Journal of Molecular Biology 202: 913-915). 4877-3368 Counter The promoter region of the anther-specific gene TA29 from clockwise Nicotiana tabacum. The promoter comprises the 1.5 kb of the sequence upstream from the ATG initiation codon (Seurinck et al. (1990) Nucleic Acids Research 18: 3403). 4878-4921 Synthetic polylinker derived sequences 4922-4946 Left border repeat from the TL-DNA from pTiB6S3 (Gielen et al (1984) The EMBO Journal 3: 835-846).

1.2. Construction of the Chimeric DNA Comprising the Barstar Gene under the Control of a Constitutive Promoter (pTHW118).

Plasmid pTHW118 was also essentially derived from the intermediate vector pGSV1 (described above). A full description of the T-DNA comprised between the border repeats of pTHW118 (SEQ ID No. 2) is given in Table 2:

TABLE 2 T-DNA of plasmid pTHW118 nt positions Orientation Description and references  1-25 Right border repeat from the TL-DNA from pTiB6S3 (Gielen et al (1984) The EMBO Journal 3: 835-846). 26-53 Synthetic polylinker derived sequences 54-90 Residual sequence from the TL-DNA at the right border repeat. 91-97 Synthetic polylinker derived sequences. 309-98  Counter The 3′untranslated end from the TL-DNA gene 7 (3′g7) of pTiB6S3 clockwise (Velten and Schell. (1985) Nucleic Acids Research 13: 6981-6998; Dhaese et al. (1983) The EMBO Journal 3: 835-846). 310-330 Synthetic polylinker derived sequences 883-331 Counter The coding sequence of the bialaphos resistance gene (bar) of clockwise Streptomyces hygroscopicus (Thompson et al. (1987) The EMBO Journal 6: 2519-2523). The N-terminal two codons of the wild type bar coding region have been substituted for the codons ATG and GAC respectively. 2608-883  Counter The promoter from the atS1A ribulose-1,5-biphosphate carboxylase clockwise small subunit gene from Arabidopsis thaliana (PssuAra) (Krebbers et al. (1988) Plant Molecular Biology 11: 745-759). 2609-2658 Synthetic polylinker derived sequences 2919-2659 Counter A 260 bp TaqI fragment from the 3′ untranslated end of the clockwise nopaline synthase gene (3′nos) from the T-DNA of pTiT37 and containing plant polyadenylation signals (Depicker et al. (1982) Journal of Molecular and Applied Genetics 1: 561-573). 2920-2940 Synthetic polylinker derived sequences 2941-2980 3′untranslated region downstream from the barstar coding sequence from Bacillus amyloliquefaciens 3253-2981 Counter The coding region of the barstar gene from Bacillus clockwise amyloliquefaciens (Hartley (1988) Journal of Molecular Biology 202: 913-915). 4762-3254 Counter The promoter region of the anther-specific gene TA29 from clockwise Nicotiana tabacum. The promoter comprises the 1.5 kb of the sequence upstream from the ATG initiation codon (Seurinck et al. (1990) Nucleic Acids Research 18: 3403). 4763-4807 Synthetic polylinker derived sequences 4808-4832 Left border repeat from the TL-DNA from pTiB6S3 (Gielen et al (1984) The EMBO Journal 3: 835-846).

1.3. Transformation of Brassica Napus

For transformation of Brassica napus the vector system as described by Deblaere et al. (1985, 1987) was used. The vector system consists of an Agrobacterium strain and two plasmid components: 1) a non-oncogenic Ti-plasmid (pGV400) and 2) an intermediate cloning vector based on plasmid pGSV1. The non-oncogenic Ti-plasmid from which the T-region has been deleted carries the vir genes required for transfer of an artificial T-DNA cloned on the second plasmid to the plant genome. The Agrobacterium strains resulting from the triparental mating between these components can be used for plant transformation.

Selection was done on phosphinothricin (PPT) at all stages except plantlet regeneration, which was done in the absence of PPT to accelerate growth. This resulted in a set of primary transformants (plants of generation T₀).

Example 2 Development of Events

2.1. Characterization of Transgenic Events

2.1.1. Southern Blot Analysis of MS Events

Presence of the transgene and the number of gene insertions were checked by standard Southern blot analysis. Total genomic DNA is isolated from 1 g of shoot tissue according to Dellaporta (1983, Plant Molecular Biology Reporter, 1, vol.3, p.19-21 or Doyle et al. 1987, Phytochem. Bull. 19:11) and digested with SacI restriction enzyme. SacI has a unique restriction site within the T-DNA fragment, situated between the barnase and bar constructs. Southern analysis was performed with the following two probes:

“barnase” probe: 478 bp PstI-EcoRI fragment of plasmid pVE113

“bar” probe: 546 bp NcoI-BglII fragment of plasmid pDE110

Plasmid pVE113 and pDE110 are described in FIG. 1 and WO 92/09696 respectively. Hybridisation of the MS events with the barnase probe yielded a 12 Kb band, while hybridization with the bar probe yielded a 14 Kb fragment.

The relative band intensity provided an indication on whether plants were homozygous or hemizygous for the transgenic locus. Two events were found to have simple insertions. This was confirmed by the fact that the segregation pattern of the transgene could be explained by Mendelian inheritance of a simple locus.

2.1.2. Southern Blot Analysis of RF Events

Presence of the transgene and the number of gene insertions were checked by standard Southern blot analysis. Total genomic DNA was isolated from 1 g of shoot tissue (according to Doyle et al. 1987, Phytochem. Bull. 19:11) and digested with SacI restriction enzyme. SacI has a unique restriction site within the T-DNA fragment, situated between the barnase and bar constructs. Southern analysis was performed with the following two probes:

“barstar” probe: 436 bp HindIII-PstI fragment of plasmid pVE113

“bar” probe: 546 bp NcoI-BglII fragment of plasmid pDE110

Hybridisation of the RF events with the barstar probe yielded a 3 Kb band, while hybridization with the bar probe yielded a 14 Kb fragment.

The relative band intensity provided an indication on whether plants were homozygous or hemizygous for the transgenic locus. Several events were found to have simple insertions. This was confirmned by the fact that the segregation pattern of the transgene could be explained by Mendelian inheritance of a simple locus.

2.1.3. General Plant Phenotype and Agronomic Performance

T₁ plants of both MS and RF events were evaluated for a number of phenotypic traits including plant height, strength/stiffness of straw, tendency to lodge, shatter resistance, drought tolerance, disease resistance (Black leg, Light leafspot, Scierotinia) and grain production and yield.

Lines were evaluated to be similar (or improved) in displayed agronomic characteristics compared to the untransformed variety as well as a number of oilseed rape cultivars. In some cases, the plants segregated for somaclonal variation for one or more of the above-mentioned traits. Unless this resulted in the introduction of a commercially interesting phenotypic trait. these plants were discarded.

2.2. Development of Lines Carrying the MS or RF Trait

The various T₀ hemizygous plantlets (“Ms/−” or “Rf/−”) were transitioned from tissue culture, transferred to greenhouse soil. Presence of the transgene and copy number was checked by southern blot analysis (described above). The plants were allowed to flower and sterility or fertility of flowers was evaluated respectively. The To plants were crossed with wildtype plants (−/−) to produce T1 seed (MsT1 and RfF1). T1 seeds were planted and grown up in the greenhouse. Plants were evaluated for tolerance to glufosinate ammonium. Ms-T1 plants were also evaluated for sterility/fertility segregation (in non-sprayed plants), while Rf-T1 plants were checked for fertile flowers. Ms-T1 plants comprising the transgene were crossed with a tester plant homozygous for a fertility restorer gene (Rf/Rf), for the production of MsRf-F1 seed. This seed (Ms/−, Rf/− and −/−, Rf/−) was planted in the greenhouse and sprayed with Liberty™. Remaining F1 progeny is evaluated for fertility/sterility segregation to test whether the male sterility trait could be adequately restored in Brassica napus (fertility close to 100%).

The best events were selected for further testing. Ms-T₁ plants were crossed with a homozygous fertility restorer and the seed was planted in the field. Plants were evaluated for tolerance to the Liberty™ herbicide (at 800 grams active ingredient per hectare (g.a.i./ha) recommended dosage for farmers is 400 g.a.i./ha), for fertility/sterility segregation and for general phenotypic characteristics. The lines in which fertility was 100% restored and for which no negative penalties on phenotype or agronomic performance (detailed under (d)) was observed as compared to the wild-type isogenic control were selected.

Rf-T1 plants comprising the transgene were crossed with a tester plant comprising the male sterility gene (Ms/−), for the production of F1 seed. This seed was planted in the greenhouse, sprayed with Liberty™ and restoration of fertility was evaluated (close to 100%).

Meanwhile Rf-T1 plants are selfed to produce S1. The S1 plants are grown in the greenhouse, sprayed with Liberty™ and again selfed to produce S2; from the S2, homozygous individuals were selected.

2.3. Combination of MS and RF Events.

The selected Ms-T1 plants were crossed with the selected Rf-S2 events in the greenhouse for fertility restoration testing. The seed was replanted in the greenhouse, plants were sprayed with Liberty™ and fertility of the flowers was checked.

2.4. Testing of MS and RF Events in Different Genetic Backgrounds and in Different Locations

The selected events were introduced into two different genetic backgrounds which are heterotically distinct, to prove that the MS and RF events function well and have no negative penalty on yield or quality in any background tested.

At the same time the selected MS and RF events are tested in four to five different environments to ensure that there is no negative interaction between environment and the MS or RF events.

In a next stage the production of hybrid seed using the selected MS and RF events was tested more extensively in the field. The selected MS event in its original background and in two different and heterotically distinct backgrounds was crossed with the selected RF event in its original background and two different and heterotically distinct backgrounds. The F1 hybrid was evaluated for resistance to Liberty for fertility, as well as overall agronomic performance (yield and quality).

2.5. Selection of Elite Events

The above described selection procedure in the development of transgenic MS lines, yielded several elite events which displayed optimal expression of the transgene, i.e. resistance to glufosinate ammonium, a male-sterile phenotype and susceptibility to complete fertility restoration with a homozygous restorer line, more specifically with the selected RF elite event.

The above described selection procedure in the development of transgenic RF lines, yielded several elite events which displayed optimal expression of the transgene, i.e. resistance to the glufosinate ammonium and the ability to restore fertility of the F1 when crossed with a plant carrying a male sterility gene, more specifically with the selected MS elite event.

Example 3 Introduction of Candidate Elite Events Selected into WOSR

Several MS and RF elite events which were developed in B. napus as described above were Gintroduced by repeated backcrossing of Drakkar variety plants, into a WOSR cultivar.

Plants were examined and it was established that:

a) the presence of the foreign DNA did not compromise other desired characteristics of the plant, such as those relating to agronomic performance or commercial value;

b) the event was characterized by a well defined molecular configuration which was stably inherited;

c) the gene(s) of interest in the foreign DNA showed a correct, appropriate and stable spatial and temporal phenotypic expression, both in heterozygous (or hemizygous) and homozygous condition of the event, at a commercially acceptable level in a range of environmental conditions in which the plants carrying the event are likely to be exposed in normal agronomic use;

Furthermore, the plants were evaluated for their agronomical characteristics and performance as compared with wild-type WOSR species.

Extensive testing in the field demonstrated that certain canditate elite events of spring oilseed rape, when introduced into WOSR resulted in plants which showed adequate expression of the genes of interest in the foreign DNA, combined with optimal agronomic performance. These events were selected as MS and RF elite events in WOSR and were named MS-BN1 and RF-BN1 respectively.

Example 4 Characterization of Elite Events MS-BN1 and RF-BN1

Once the MS-BN1 and RF-BN1 events were identified as the elite events in which expression of the respective transgenes as well as overall agronomic performance were optimal, the loci of the transgenes were analyzed in detail on a molecular level. This included detailed Southern blot analysis (using multiple restriction enzymes) and sequencing of the flanking regions of the transgene.

4.1. Southern Blot Analysis Using Multiple Restriction Enzymes

Leaf tissue was harvested from transgenic and control plants. Total genomic DNA was isolated from leaf tissue according to Dellaporta et al. (1983, Plant Molecular Biology Reporter, 1, vol.3, p. 19-21). The DNA concentration of each preparation was determined by measuring the optical density in a spectrophotometer at a wavelength of 260 nm.

10 μg of genomic DNA was digested with restriction enzyme in a final reaction volume of 40 μl, applying conditions proposed by the manufacturer. The time of digestion and/or amount of restriction enzyme were adjusted to ensure complete digestion of the genomic DNA samples without non-specific degradation. After digestion, 4 μl of loading dye was added to the digested DNA samples, and they were loaded on a 1% agarose gel.

The following control DNAs were also loaded on the gel:

a negative control with genomic DNA prepared from a non-transgenic Brassica plant. This negative control is used to confirm the absence of background hybridization.

a DNA positive control: With a heterozygous single copy integration of the transgene into the Brassica napus genome, 10 μg of genomic DNA has the same number of molecule equivalents as ±19 picogram of 1501 bp PvuI-HindIII fragment of pTHW118 DNA (Brassica napus diploid genome size: 0.8×10⁹ bp). The amount representing one plasmid copy per genome is added to 1 μg of digested non-transgenic Brassica napus DNA. This reconstitution sample is used to show that the hybridizations are performed under conditions allowing hybridization of the probe with target sequences.

Phage Lambda DNA (strain Clind 1 ts 857 Sam 7, Life Technologies) digested with PstI was included as size standard.

After electrophoresis, the DNA samples (digested Brassica genomic DNA, controls and size standard DNA) were transferred to a Nylon membrane by capillary blotting during 12 to 16 hours.

The DNA templates used for probe preparation for MS-BN1 events were prepared by restriction digestion of PTW107 with HindIII. This released a 3942 bp DNA fragment that encompasses a relevant part of the transforming DNA (part of PSSUARA, 3′nos, barnase, PTA29).

The DNA templates used for probe preparation for RF-BN1 events were prepared by restriction digestion of PTW118 with HpaI. This released a 2182 bp DNA fragment that encompasses a relevant part of the transforming DNA (part of PSSUARA, 3′nos, barstar, PTA29).

After purification, the DNA fragments were labeled according to standard procedures, and used for hybridizing to the membrane.

Hybridization was performed under standard stringency conditions: The labeled probe was denaturated by heating for 5 to 10 minutes in a water bath at 95° C. to 100° C. and chilling on ice for 5 to 10 minutes and added to the hybridization solution (6×SSC (20×SSC is 3.0 M NaCl, 0.3 M Na citrate, pH 7.0), 5×Denhardt's (100×Denhardt's=2% Ficoll, 2% Polyvinyl pyrollidone, 2% Bovine Serum Albumin), 0.5% SDS and 20 μg/ml denatured carrier DNA (single-stranded fish sperm DNA, with an average length of 120-3000 nucleotides). The hybridization was performed overnight at 65° C. The blots were washed three times for 20 to 40 minutes at 65° C., with the wash solution (2×SSC, 0.1% SDS).

The autoradiographs were electronically scanned.

4.1.1. MS-BN1

The restriction patterns obtained after digestion of MS-BN1 genomic DNA with different restriction enzymes is presented in FIG. 2 and summarized in Table 3.

TABLE 3 Restriction map of MS-BN1 Estimated Migration of hybridizing length of the DNA fragments between hybridizing Lane size marker bands DNA number DNA loaded Larger than Smaller than fragments. 1 MS-BN1-EcoRI 2140 2450 2266 bp (*) 14057 — >14 kbp 2 MS-BN1-EcoRV 1159 1700  1.4 kbp (*) 14057 — >14 kbp 4 MS-BN1-HpaI 1986 2140 1990 bp 2140 2450 2229 bp 5 MS-BN1-Af1III 2450 2838 2477 bp (*) 2140 2450 2250 bp 514 805  552 bp (*) 6 MS-BN1-NdeI 5077 14057  10 kbp 5077 14057 6510 bp 7 Non-transgenic — — — WOSR 8 Control plasmid 1700 1986 1966 bp (*) DNA-BamHI 2450 2838 2607 bp (*) (*) the lengths of these fragments are those predicted from the restriction map of the plasmid pTHW107

4.1.2. RF-BN1

The restriction patterns obtained after digestion of RF-BN1 genomic DNA with different restriction enzymes is presented in FIG. 3 and summarized in Table 4.

TABLE 4 Restriction map of RF-BN1 Estimated Migration of hybridizing length of the DNA fragments between hybridizing Lane size marker bands DNA number DNA loaded Larger than Smaller than fragments. 1 MS-BN1-BamHI 805 1099  814 bp 1700 1986 1849 bp (*) 2450 2838 2607 bp (*) 5077 14057 6580 bp 2 MS-BN1-EcoRI 805 1159 1094 bp 1986 2450 2149 bp 5077 14057 7000 bp 5077 14057  10 kbp 3 MS-BN1-EcoRV 5077 14057 5.4 kbp 5077 14057   8 kbp 4 MS-BN1-HindIII 1700 2140 1969 bp 2450 2838 2565 bp 2450 2838 2635 bp 6 Non-transgenic — — — WOSR 5 Control plasmid 1700 1986 1849 bp (*) DNA-BamHI 2450 2838 2607 bp (*) 5077 14057 8100 bp (*) the lengths of these fragments are those predicted from the restriction map of the pTHW118 vector with BamHI.

4.2. Identificatioin of the Flanking Regions

Flanking regions of the elite events MS-BN1 and RF-BN1 were first identified for spring ORS, in which the events were edveloped, and then checked for WOSR.

4.2.1. Identification of the Flanking Regions of MS-BN1

4.2.1.1. Right (5′) Flanking Region

The sequence of the right flanking region of MS-BN1, a ligation-mediated polymerase chain reaction (Mueller et al. 1989, Science 780-786; Maxine t al., 1994, PCR Methods and Application, 71-75) with extension capture (Törmanen et al., 1993, NAR 20:548-5488) was used.

The oligonucleotides used for linker preparation were:

MDB248: (SEQ ID No. 3)

5′CAT.GCC.CTG.ACC.CAG.GCT.AAG.TAT.TTT.AAC.TTT.AAC.CAC.TTT.GCT.CCG.ACA.GTC.CCA.TTG

MDB249: (SEQ ID No. 4)

5′CAA.TGG.GAC.TGT.CGG.AGG.ACT.GAG.GGC.CAA.AGC,TTG.GCT.CTT.AGC.CGT.GGT.CAG.GGC.ATG

Preparation of the linker was followed by first strand synthesis from genomic MS-BN1 DNA digested with NcoI, using a biotinylated gene-specific primer:

Position in Sequence (5′→3′) pTHW107 Biotinylated primer CCG.TCA.CCG.AGA.TCT.GAT.CTC.ACG.CG 322←347 MDB247 (SEQ ID No. 5)

The linker was then ligated to the first strand DNA, which was then coupled to magnetic beads from which the non-biotinylated strand was eluted. This DNA was used in an upscaled PCR amplification using the following primers:

Position in Sequence (5′→3′) pTHW107 Linker GCACTGAGGGCCAAAGCTTGGCTC — primer (SEQ ID No. 6) MDB250 T-DNA GGA.TCC.CCC.GAT.GAG.CTA.AGC.TAG.C 293←317 primer (SEQ ID No. 7) MDB251

This PCR yielded a fragment of about 1150 bp. This Right Border fragment was eluted out of an agarose gel and a nested PCR was done on a 100 fold dilution of this DNA using the following primers:

Position in Sequence (5′→3′) pTHW107 Nested linker CTTAGCCTGGGTCAGGGCATG — primer MDB254 (SEQ ID No. 8) T-DNA primer CTA.CGG.CAA.TGT.ACC.AGC.TG 224←243 MDB258 (SEQ ID No. 9)

This yielded a fragment of about 1000 bp, which was eluted out of the agarose gel, purified, and ligated to the pGem®-T Vector. The recombinant plasmid DNA was screened using a standard PCR reaction with the following primers:

Position in Sequence (5′→3′) pTHW107 SP6 TAA.TAC.GAC.TCA.CTA.TAG.GGC.GA — primer (SEQ ID No. 10) (SP6 promoter in pGem ®-T Vector) T7 TTT.AGG.TGA.CAC.TAT.AGA.ATA.C — primer (SEQ ID No. 11) (T7 promoter in pGem ®-T Vector) T-DNA GCT.TGG.ACT.ATA.ATA.CCT.GAC 143←163 primer (SEQ ID NO. 12) MDB201

This yielded the following fragments: SP6-T7: 1224 bp

SP6-MDB201: 1068 bp

T7-MDB201: 1044 bp

The right border fragment was purified and sequenced (SEQ ID No. 13) resulting in 953 bp of which bp 1-867 corresponds to plant DNA and bp 868 to 953 corresponds to T-DNA of pTW107.

4.2.1.2. Left (3′) Flanking Region of MS-BN1

The sequence of the left border region flanking the inserted transgene in the MS-BN1 event were determined using the thermal asymmetric interlaced (TAIL-) PCR method as described by Liu et al. (1995, The Plant Journal 8(3): 457-463). This method utilizes three nested specific primers in successive reactions together with a shorter arbitrary degenerate (AD) primer so that the relative amplification efficiencies of specific and non-specific products can be thermally controlled. The specific primers were selected for annealing to the border of the transgene and based on their annealing conditions. A small amount (5 μl) of unpurified secondary and tertiary PCR products were analyzed on a 1% agarose gel. The tertiary PCR product was used for preparative amplification, purified and sequenced on an automated sequencer using the DyeDeoxy Terminator cycle kit.

The following primers were used:

Position in Sequence (5′→3′) pTHW107 Degenerate primer NgT.CgA.SWg.TNT.WCA.A — MDB611 (SEQ ID No. 14) Primary TAIL gTg.Cag.ggA.AgC.ggT.TAA.CTg.g. 7164→4186 MDB259 (SEQ ID No. 15) Second. TAIL CCT.TTg.gAg.TAA.ATg.gTg.TTg.g 4346→4366 MDB260 (SEQ ID No. 16) Tertiary TAIL gCg.AAT.gTA.TAT.TAT.ATg.CA 473 8→4757 HCA24 (SEQ ID No. 17) whereby: N = A,C,T or g; S=C or g; W = A or T

The fragment amplified using HCA24-MDB611 was ca. 540 bp of which 537 bp were sequenced (3′ flank: SEQ ID No 18). The sequence between bp 1 and bp 180 comprised pTHW107 DNA, while the sequence between bp 181 and bp 537 corresponded to plant DNA.

4.2.1.3. Identification of the Target Site Deletion

Using primers corresponding to sequences within the flanking regions of the transgene on the wildtype Brassica napus var. Drakkar as a template, the insertion site of the transgene was identified.

The following primers were used:

(SEQ ID (SEQ ID Sequence (5′→3′) No 13) No 18) VDS51 TgA.CAC.TTT.gAg.CCA.CTC.g-- 733→751 — (SEQ ID No 19) HCA48 GgA.ggg.TgT.TTT.tgg.TTA.TC — 189←208 (SEQ ID No 20)

This yielded a 178 bp fragment (SEQ ID No 21) in which bp 132 to 150 corresponds to a target site deletion.

4.2.1.4. Identification of the MS-BN1 Insertion Region

Based on the identification of the flanking regions, and the target site deletion the insertion region of MS-BN1 could be determined (SEQ ID No 22):

Plant DNA primer:

MDB288 ATg.CAg.CAA.gAA.gCT.Tgg.Agg (SEQ ID No. 29)

T-DNA primer:

MDB314 gTA.ggA.ggT.Tgg.gAA.gAC.C (SEQ ID No. 26)

4.2.2. Identification of the Flanking Regions of RF-BN1

The border flanking regions of RF-BN1 were determined by Vectorette-PCR (Use of Vectorette and Subvectorette PCR to isolate transgene flanking DNA, Maxine J. Allen, Andrew Collick, and Alec J. Jeffreys PCR Methods and Applications—1994 (4) pages 71-75) with RF-BN1 genomic DNA digested with HindIII as a template. The vectorette linker was made using the primers MDB248 (SEQ ID No. 3) and MDB249 (SEQ ID No. 4) primers described above.

4.2.2.1. Right (5′) Flanking Region of BN-RF1

The following primers were used:

Position in Sequence (5′→3′) pTHW107 Vectorette GCA.CTG.AGG.GCC.AAA.GCT.TGG.CTC — primer (SEQ ID No. 6) MDB250 Vectorette CTT.AGC.CTG.GGT.CAG.GGC.ATG — primer (SEQ ID No. 8) MDB254 T-DNA GGA.TCC.CCC.GAT.GAG.CTA.AGC.TAG.C 293←317 primer (SEQ ID No. 7) MDB251 T-DNA TCA.TCT.ACG.GCA.ATG.T.AC.CAG.C 226←247 primer (SEQ ID No. 23) MDB193 T-DNA CTA.CGG.CAA.TGT.ACC.AGC.TG 224← 243 primer (SEQ ID No. 9) MDB258 T-DNA GCT.TGG.ACT.ATA.ATA.CCT.GAC 143←163 primer (SEQ ID NO. 12) MDB201

This yielded a 1077 bp fragment (SEQ ID No. 24) in which bp 46-881 corresponds to plant DNA and bp 882-1060 corresponds to T-DNA of pTW118.

4.2.2.2. Left (3′) Flanking Region of BN-RF1

To identify the 3′ flanking region of elite event BN-RF1, a TAIL PCR was performed as described above using an Arbitrary degenerate primer and primers located in the T-DNA in the vicinity of the left border.

The primers used were:

Arbitrary Degenerate Primer:

MDB286 NTg.CgA.SWg.ANA.WgA.A (SEQ ID No. 25)

whereby: N=A,C,T or g; S=C or g; W=A or T

T-DNA primers:

MDB314 gTA.ggA.ggT.Tgg.gAA.gAC.C (SEQ ID No. 26)

MDB315 ggg.CTT.TCT.ACT.AgA.AAg.CTC.TCg.g (SEQ ID No. 27)

MDB316 CCg.ATA.ggg.AAg.TgA.TgT.Agg.Agg (SEQ ID No. 28)

A fragment of about 2000 bp was obtained. This fragment was cloned in a pGem®-T Vector and used as a template for a PCR reaction using the following primers:

Plant DNA primer:

MDB288 ATg.CAg.CAA.gAA.gCT.Tgg.Agg SEQ ID No. 29)

T-DNA primer:

MDB314 gTA.ggA.ggT.Tgg.gAA.gAC.C (SEQ ID No. 26)

This yielded a fragment of about 1500 bp (SEQ ID No. 30) wherein bp 17-182 corresponds to T-DNA from plasmid pTW118 and bp 183-1457 corresponds to plant DNA.

4.2.2.3. Molecular Analysis of the Target-site Deletion

The target site deletion was cloned with the TAIL-PCR method (described above), using wild type genomic DNA and plant DNA specific primers upstream of the T-DNA insert directed towards the insert:

Arbitrary Degenerate primer:

MDB286 NTg.CgA.SWg.ANA.WgA.A (SEQ ID No. 25)

whereby: N=A,C,T or g; S=C or g; W=A or T

Plant DNA primers:

MDB269 ggTTTTCggAggTCCgAgACg (SEQ ID No. 31)

MDB283 CTTggACCCCTAggTAAATgC (SEQ ID No. 32)

MDB284 gTACAAAACTTggACCCCTAgg (SEQ ID No. 33)

A fragment of 1068 bp (SEQ ID No.34) was obtained, in which:

53-83: 5′ flanking region

84-133: target site deletion

134-1055: 3′ flanking region

Upon insertion of the T-DNA, 51 bp of the target site were deleted. Comparing the wild type locus sequence with the Rf3 locus revealed the presence of filler DNA at the right border junction. The filler TCTCG sequence at the right border is flanked by TCA at the 5′end and CGA at the 3′end. These triplets are also found at the breakpoint of the target site deletion and the T-DNA respectively. A search in more distal plant sequences revealed a possible origin of this filler DNA. The TCA.TCTCG.CGA (SEQ ID NO: 44) sequence is also located in the plant DNA at the 3′end of the target site deletion. It is the core sequence of two 13 bp identical repeats located 209 bp downstream of the breakpoint of the target site deletion.

The insertion region for RF-BN1 can be defined as comprising the left flanking region, the target site deletion and the right flanking region as follows:

1-836: 5′flanking region (bp 46-881 of SEQ ID No 24)

837-887: target site deletion (bp 84-133 of SEQ ID No. 34)

888-2126 3′ flanking region (bp 183-1457 of SEQ ID No. 30)

4.3. Genetic Analysis of the Locus

The genetic stability of the inserts for the two events was checked by molecular and phenotypic analysis in the progeny plants over several generations.

Southern blot analyses of plants of the T₀, T₁ and T₂ generation were compared for both event MS-BN1 and RF-BN1. The patterns obtained were found to be identical for each of the events in the different generations. This proves that the molecular configuration of the transgenes in both MS-BN1 and RF-BN1 containing plants was stable.

The MS-BN1 and RF-BN1 events displayed Mendelian segregation for their respective transgenes as single genetic loci in at least three subsequent generations indicating that the inserts are stable.

On the basis of the above results MS-BN1 and MS-RF1 were identified as elite events.

4.4. Identification of the Flanking Sequences of MS-BN1 and RF-BN1 in WOSR

The flanking sequences of the elite events MS-BN1 and RF-BN1 in WOSR were determined using primers which were developed based on the flanking sequences of these events in spring oilseed rape. MS-BN1 WOSR right (5′) flanking sequence was determined using a T-DNA primer (SEQ ID No. 12) and a primer located in the MS-BN1 right border plant DNA:

VDS57: 5′-gCA.TgA.TCT.gCT. Cgg.gAT.ggC-3′ (SEQ ID No. 35)

This yielded a fragment of 909 bp (SEQ ID No. 36) with a sequence essentially similar to the sequence of SEQ ID No. 13 (starting from nucleotide 98).

MS-BN1 WOSR left (3′) flanking sequence was determined using a T-DNA primer (SEQ ID No. 17) and a primer located in the MS-BN1 left border plant DNA:

HCA68: 5′-CCA.TAT.Acg.CCA.gAg.Agg.AC-3′ (SEQ ID No. 37)

This yielded a fragment of 522 bp (SEQ ID No. 38) with a sequence essentially similar to the sequence of SEQ ID No. 18.

RF-BN1 WOSR right (5′) flanking sequence was determined using a T-DNA primer (SEQ ID No. 12) and a primer located in the RF-BN1 right border plant DNA (SEQ ID No. 31). This yielded a fragment of 694 bp (SEQ ID No. 39) with a sequence essentially similar to the sequence of SEQ ID No. 24 (from nucleotide 293 to 980).

RF-BN WOSR left border sequence was determined using a T-DNA primer (SEQ ID No. 26) and a primer located in the RF-BN1 left border plant DNA (SEQ ID No. 29). This yielded a fragment of 1450 bp of which 1279 were sequenced (SEQ ID No. 40). This sequence was found to be essentially similar to the sequence of SEQ ID No. 30 (from nucleotide 141 to 1421).

Thus, left and right border sequences of the elite events MS-BN1 and RF-BN1 were confirmed to be essentially similar in SOSR and WOSR.

Example 5 Development of Diagnostic Tools for Identity Control

The following protocols were developed to identify any WOSR plant material comprising the elite event MS-BN1.

5.1. MS-BN1 and RF-BN1 Elite Event Restriction Map Identification Protocol

WOSR plants containing the elite event MS-BN1 can be identified by Southern blotting using essentially the same procedure as described in Example 4.1. Thus WOSR genomic DNA is 1) digested with at least two, preferably at least 3, particularly with at least 4, more particularly with all of the following restriction enzymes: EcoRI, EcoRV, NdeI, HpaI, AflIII 2) transferred to nylon membranes and 3) hybridized with the 3942 bp HindIII fragment of plasmid pTHW107. If, with respect to at least two of the restriction enzymes used, DNA fragments are identified with the same length as those listed in Table 3 of Example 4.1.1., the WOSR plant is determined to harbor elite event MS-BN1.

WOSR plants containing the elite event RF-BN1 can be identified by Southern blotting using essentially the same procedure as described in Example 4.1. Thus WOSR genomic DNA is 1) digested with at least two, preferably at least three, most preferably with all of the following restriction enzymes: BamHI, EcoRI, EcoRV, HindIII 2) transferred to nylon membranes and 3) hybridized with the 2182 bp HpaI fragment of plasmid pTHW118. If, with respect to at least two of the restriction enzymes used, DNA fragments are identified with the same length as those listed in Table 4 in Example 4.1.2., the WOSR plant is determined to harbor elite event RF-BN1.

5.2. MS-BN1 and RF-BN1 Elite Event Polymerase Chain Reaction Identification Protocol

A test run, with all appropriate controls, has to be performed before attempting to screen unknowns. The presented protocol might require optimization for components that may differ between labs (template DNA preparation, Taq DNA polymerase, quality of the primers, dNTP's, thermocyler, etc.).

Amplification of the endogenous sequence plays a key role in the protocol. One has to attain PCR and thermocycling conditions that amplify equimolar quantities of both the endogenous and transgenic sequence in a known transgenic genomic DNA template.

Whenever the targeted endogenous fragment is not amplified or whenever the targeted sequences are not amplified with the same ethidium bromide staining intensities, as judged by agarose gel electrophoresis, optimization of the PCR conditions may be required.

5.2.1. Template DNA

Template DNA is prepared from a leaf punch or a single seed according to Edwards et al. (Nucleic Acid Research, 19, p1349, 1991). When using DNA prepared with other methods, a test run utilizing different amounts of template should be done. Usually 50 ng of genomic template DNA yields the best results.

5.2.2. Assigned Positive and Negative Controls

The following positive and negative controls should be included in a PCR run:

Master Mix control (DNA negative control). This is a PCR in which no DNA is added to the reaction. When the expected result, no PCR products, is observed this indicates that the PCR cocktail was not contaminated with target DNA.

A DNA positive control (genomic DNA sample known to contain the transgenic sequences). Successful amplification of this positive control demonstrates that the PCR was run under conditions which allow for the amplification of target sequences.

A wildtype DNA control. This is a PCR in which the template DNA provided is genomic DNA prepared from a non-transgenic plant. When the expected result, no amplification of the transgene PCR product but amplification of the endogenous PCR product, is observed this indicates that there is no detectable transgene background amplification in a genomic DNA sample.

The following primers, which specifically recognize the transgene and a flanking sequence of MS-BN1 are used:

BNA01: 5′-gCT.Tgg.ACT.ATA.ATA.CCT.gAC-3′ (SEQ ID 12)

(MDB201) (target: transgene)

BNA02: 5′-TgA.CAC.TTT.gAg.CCA.CTC.g-3′ (SEQ ID 19)

(VDS51) (target: plant DNA)

To identify plant material comprising RF-BN1, the following primers, which specifically recognize the transgene and a flanking sequence of RF-BN1 are used:

BNA03: 5′-TCA.TCT.ACg.gCA.ATg.TAC.Cag.C-3′ (SEQ ID 23)

(MDB193) (target: transgene)

BNA04: 5′-Tgg.ACC.CCT.Agg.TAA.ATg.CC-3′ (SEQ ID 41)

(MDB268) (target: plant DNA)

Primers targeting an endogenous sequence are always included in the PCR cocktail. These primers serve as an internal control in unknown samples and in the DNA positive control. A positive result with the endogenous primer-pair demonstrates that there is ample DNA of adequate quality in the genomic DNA preparation for a PCR product to be generated. The endogenous primers used are:

BNA05: 5′-AAC.gAg.TgT.CAg.CTA.gAC.CAg.C-3′ (SEQ ID 42)

BNA06: 5′-CgC.AgT.TCT.gTg.AAC.ATC.gAC.C-3′ (SEQ ID 43)

5.2.4. Amplified Fragments

5.2.4. Amplified Fragments

The expected amplified fragments in the PCR reaction are:

For primer pair BNA05-BNA06: 394 bp (endogenous control)

For primer pair BNA01-BNA02: 280 bp (MS-BN1 Elite Event)

For primer pair BNA03-BNA04: 215 bp (RF-BN1 Elite Event)

5.2.5. PCR Conditions

The PCR mix for 50 μl reactions contains:

5 μl template DNA

5 μl 10× Amplification Buffer (supplied with Taq polymerase)

1 μl 10 mM dNTP's

1 μl BNA01 (MS-BN1) or BNA03 (RF-BN1)(10 pmoles/μl)

1 μl BNA02 (RF-BN1) or BNA04 (RF-BN1) (10 pmoles/μl)

0.5 μl BNA05 (10 pmoles/μl)

0.5 μl BNA06 (10 pmoles/μl)

0.2 μl Taq DNA polymerase (5 units/μl)

water up to 50 μl

The thermocycling profile to be followed for optimal results is the following:

4 min. at 95° C.

Followed by: 1 min. at 95° C.

1 min. at 57° C.

2 min. at 72° C.

For 5 cycles

Followed by: 30 sec. at 92° C.

30 sec. at 57° C.

1 min. at 72° C.

For 22 to 25 cycles

Followed by: 5 minutes at 72° C.

5.2.6. Agarose Gel Analysis

Between 10 and 20 μl of the PCR samples should be applied on a 1.5% agarose gel (Tris-borate buffer) with an appropriate molecular weight marker (e.g. 100 bp ladder PHARMACIA).

5.2.7. Validation of the Results

Data from transgenic plant DNA samples within a single PCR run and a single PCR cocktail should not be acceptable unless 1) the DNA positive control shows the expected PCR products (transgenic and endogenous fragments), 2) the DNA negative control is negative for PCR amplification (no fragments) and 3) the wild-type DNA control shows the expected result (endogenous fragment amplification).

Lanes showing visible amounts of the transgenic and endogenous PCR products of the expected sizes, indicate that the corresponding plant from which the genomic template DNA was prepared, has inherited the MS-BN1 and/or RF-BN1 elite event. Lanes not showing visible amounts of either of the transgenic PCR products and showing visible amounts of the endogenous PCR product, indicate that the corresponding plant from which the genomic template DNA was prepared, does not comprise the elite event. Lanes not showing visible amounts of the endogenous and transgenic PCR products, indicate that the quality and/or quantity of the genomic DNA didn't allow for a PCR product to be generated. These plants cannot be scored. The genomic DNA preparation should be repeated and a new PCR run, with the appropriate controls, has to be performed.

5.2.8. Use of Discriminating PCR Protocol to Identify MS-BN1 and RF-BN1

WOSR leaf material from plants comprising either MS-BN1, RF-BN1 or another transgenic event was tested according to the above-described protocol. Samples from WOSR wild-type were taken as negative controls.

The results of the PCR analysis are illustrated in FIGS. 4 and 5. FIG. 4 illustrates the result obtained with the elite event PCR identification protocol for MS-BN1 on two WOSR samples (lane 1 and 2). Lane 1 is recognized to contain the elite event as the 280 bp band is detected while the sample in lane 2 does not comprise MS-BN1.

FIG. 5 illustrates the result obtained with the elite event PCR identification protocol for RF-BN1 on two WOSR samples (lane 1 and 2). Lane 1 is recognized to contain the elite event as the 215 bp band is detected while the sample in lane 2 does not comprise RF-BN1.

Example 6 Production of Hybrid Seed Using MS-BN1 and RF-BN1 in WOSR

WOSR Plants comprising MS-BN1 which were male sterile were crossed with WOSR plants homozygous for RF-BN 1. Hybrid seed was collected from MS-BN 1 and deposited at the ATCC under ATCC accession number PTA-730.

This hybrid seed was replanted in the field. Plants were found to be 100% fertile and displaying optimal agronomic characteristics. Hybrid plants comprised either both the MS-BN1 and RF-BN1 or the RF-BN-1 event alone.

Example 7 Introduction of MS-BN1 and RF-BN1 into Preferred Cultivars of WOSR

Elite events MS-BN1 and RF-BN1 were introduced by repeated backcrossing of plants comprising event MS-BN1 or RF-BN1, respectively, into a number of agriculturally important WOSR cultivars.

It was observed that the introgression of the elite events into these cultivars did not significantly influence any of the desirable phenotypic or agronomic characteristics of these cultivars (no linkage drag) while expression of the transgene, as determined by glufosinate tolerance, meets commercially acceptable levels. This confirms the status of event MS-BN1 and RF-BN1 as elite events.

As used in the claims below, unless otherwise clearly indicated, the term “plant” is intended to encompass plant tissues, at any stage of maturity, as well as any cells, tissues, or organs taken from or derived from any such plant, including without limitation, any seeds. leaves, stems, flowers, roots, single cells, gametes, cell cultures, tissue cultures or protoplasts

Seed comprising elite event MS-BN1 and elite event RF-BN1 or elite event RF-BN1 alone was deposited at the American Tissue Culture Collection under accession number: PTA-730.

The above description of the invention is intended to be illustrative and not limiting. Various changes or modifications in the embodiments described may occur to those skilled in the art. These can be made without departing from the spirit or scope of the invention.

44 1 4946 DNA Artificial Sequence misc_feature (1)..(4946) T-DNA of Plasmid pTHW107 1 aattacaacg gtatatatcc tgccagtact cggccgtcga actcggccgt cgagtacatg 60 gtcgataaga aaaggcaatt tgtagatgtt aattcccatc ttgaaagaaa tatagtttaa 120 atatttattg ataaaataac aagtcaggta ttatagtcca agcaaaaaca taaatttatt 180 gatgcaagtt taaattcaga aatatttcaa taactgatta tatcagctgg tacattgccg 240 tagatgaaag actgagtgcg atattatgtg taatacataa attgatgata tagctagctt 300 agctcatcgg gggatcctag acgcgtgaga tcagatctcg gtgacgggca ggaccggacg 360 gggcggtacc ggcaggctga agtccagctg ccagaaaccc acgtcatgcc agttcccgtg 420 cttgaagccg gccgcccgca gcatgccgcg gggggcatat ccgagcgcct cgtgcatgcg 480 cacgctcggg tcgttgggca gcccgatgac agcgaccacg ctcttgaagc cctgtgcctc 540 cagggacttc agcaggtggg tgtagagcgt ggagcccagt cccgtccgct ggtggcgggg 600 ggagacgtac acggtcgact cggccgtcca gtcgtaggcg ttgcgtgcct tccaggggcc 660 cgcgtaggcg atgccggcga cctcgccgtc cacctcggcg acgagccagg gatagcgctc 720 ccgcagacgg acgaggtcgt ccgtccactc ctgcggttcc tgcggctcgg tacggaagtt 780 gaccgtgctt gtctcgatgt agtggttgac gatggtgcag accgccggca tgtccgcctc 840 ggtggcacgg cggatgtcgg ccgggcgtcg ttctgggtcc attgttcttc tttactcttt 900 gtgtgactga ggtttggtct agtgctttgg tcatctatat ataatgataa caacaatgag 960 aacaagcttt ggagtgatcg gagggtctag gatacatgag attcaagtgg actaggatct 1020 acaccgttgg attttgagtg tggatatgtg tgaggttaat tttacttggt aacggccaca 1080 aaggcctaag gagaggtgtt gagaccctta tcggcttgaa ccgctggaat aatgccacgt 1140 ggaagataat tccatgaatc ttatcgttat ctatgagtga aattgtgtga tggtggagtg 1200 gtgcttgctc attttacttg cctggtggac ttggcccttt ccttatgggg aatttatatt 1260 ttacttacta tagagctttc ataccttttt tttaccttgg atttagttaa tatataatgg 1320 tatgattcat gaataaaaat gggaaatttt tgaatttgta ctgctaaatg cataagatta 1380 ggtgaaactg tggaatatat atttttttca tttaaaagca aaatttgcct tttactagaa 1440 ttataaatat agaaaaatat ataacattca aataaaaatg aaaataagaa ctttcaaaaa 1500 acagaactat gtttaatgtg taaagattag tcgcacatca agtcatctgt tacaatatgt 1560 tacaacaagt cataagccca acaaagttag cacgtctaaa taaactaaag agtccacgaa 1620 aatattacaa atcataagcc caacaaagtt attgatcaaa aaaaaaaaac gcccaacaaa 1680 gctaaacaaa gtccaaaaaa aacttctcaa gtctccatct tcctttatga acattgaaaa 1740 ctatacacaa aacaagtcag ataaatctct ttctgggcct gtcttcccaa cctcctacat 1800 cacttcccta tcggattgaa tgttttactt gtaccttttc cgttgcaatg atattgatag 1860 tatgtttgtg aaaactaata gggttaacaa tcgaagtcat ggaatatgga tttggtccaa 1920 gattttccga gagctttcta gtagaaagcc catcaccaga aatttactag taaaataaat 1980 caccaattag gtttcttatt atgtgccaaa ttcaatataa ttatagagga tatttcaaat 2040 gaaaacgtat gaatgttatt agtaaatggt caggtaagac attaaaaaaa tcctacgtca 2100 gatattcaac tttaaaaatt cgatcagtgt ggaattgtac aaaaatttgg gatctactat 2160 atatatataa tgctttacaa cacttggatt tttttttgga ggctggaatt tttaatctac 2220 atatttgttt tggccatgca ccaactcatt gtttagtgta atactttgat tttgtcaaat 2280 atatgtgttc gtgtatattt gtataagaat ttctttgacc atatacacac acacatatat 2340 atatatatat atatattata tatcatgcac ttttaattga aaaaataata tatatatata 2400 tagtgcattt tttctaacaa ccatatatgt tgcgattgat ctgcaaaaat actgctagag 2460 taatgaaaaa tataatctat tgctgaaatt atctcagatg ttaagatttt cttaaagtaa 2520 attctttcaa attttagcta aaagtcttgt aataactaaa gaataataca caatctcgac 2580 cacggaaaaa aaacacataa taaatttgaa tttcgaccgc ggtacccgga attcgagctc 2640 ggtacccggg gatcttcccg atctagtaac atagatgaca ccgcgcgcga taatttatcc 2700 tagtttgcgc gctatatttt gttttctatc gcgtattaaa tgtataattg cgggactcta 2760 atcataaaaa cccatctcat aaataacgtc atgcattaca tgttaattat tacatgctta 2820 acgtaattca acagaaatta tatgataatc atcgcaagac cggcaacagg attcaatctt 2880 aagaaacttt attgccaaat gtttgaacga tctgcttcgg atcctctaga gccggaaagt 2940 gaaattgacc gatcagagtt tgaagaaaaa tttattacac actttatgta aagctgaaaa 3000 aaacggcctc cgcaggaagc cgtttttttc gttatctgat ttttgtaaag gtctgataat 3060 ggtccgttgt tttgtaaatc agccagtcgc ttgagtaaag aatccggtct gaatttctga 3120 agcctgatgt atagttaata tccgcttcac gccatgttcg tccgcttttg cccgggagtt 3180 tgccttccct gtttgagaag atgtctccgc cgatgctttt ccccggagcg acgtctgcaa 3240 ggttcccttt tgatgccacc cagccgaggg cttgtgcttc tgattttgta atgtaattat 3300 caggtagctt atgatatgtc tgaagataat ccgcaacccc gtcaaacgtg ttgataaccg 3360 gtaccatggt agctaatttc tttaagtaaa aactttgatt tgagtgatga tgttgtactg 3420 ttacacttgc accacaaggg catatataga gcacaagaca tacacaacaa cttgcaaaac 3480 taacttttgt tggagcattt cgaggaaaat ggggagtagc aggctaatct gagggtaaca 3540 ttaaggtttc atgtattaat ttgttgcaaa catggactta gtgtgaggaa aaagtaccaa 3600 aattttgtct caccctgatt tcagttatgg aaattacatt atgaagctgt gctagagaag 3660 atgtttattc tagtccagcc acccacctta tgcaagtctg cttttagctt gattcaaaaa 3720 ctgatttaat ttacattgct aaatgtgcat acttcgagcc tatgtcgctt taattcgagt 3780 aggatgtata tattagtaca taaaaaatca tgtttgaatc atctttcata aagtgacaag 3840 tcaattgtcc cttcttgttt ggcactatat tcaatctgtt aatgcaaatt atccagttat 3900 acttagctag atatccaatt ttgaataaaa atagctcttg attagtaaac cggatagtga 3960 caaagtcaca tatccatcaa acttctggtg ctcgtggcta agttctgatc gacatggggt 4020 taaaatttaa attgggacac ataaatagcc tatttgtgca aatctcccca tcgaaaatga 4080 cagattgtta catggaaaac aaaaagtcct ctgatagaag tcgcaaagta tcacaatttt 4140 ctatcgagag atagattgaa agaagtgcag ggaagcggtt aactggaaca taacacaatg 4200 tctaaattaa ttgcattcgc taaccaaaaa gtgtattact ctctccggtc cacaataagt 4260 tattttttgg cccttttttt atggtccaaa ataagtgagt tttttagatt tcaaaaatga 4320 tttaattatt tttttactac agtgcccttg gagtaaatgg tgttggagta tgtgttagaa 4380 atgtttatgt gaagaaatag taaaggttaa tatgatcaat ttcattgcta tttaatgtta 4440 aaatgtgaat ttcttaatct gtgtgaaaac aaccaaaaaa tcacttattg tggaccggag 4500 aaagtatata aatatatatt tggaagcgac taaaaataaa cttttctcat attatacgaa 4560 cctaaaaaca gcatatggta gtttctaggg aatctaaatc actaaaatta ataaaagaag 4620 caacaagtat caatacatat gatttacacc gtcaaacacg aaattcgtaa atatttaata 4680 taataaagaa ttaatccaaa tagcctccca ccctataact taaactaaaa ataaccagcg 4740 aatgtatatt atatgcataa tttatatatt aaatgtgtat aatcatgtat aatcaatgta 4800 taatctatgt atatggttag aaaaagtaaa caattaatat agccggctat ttgtgtaaaa 4860 atccctaata taatcgcgac ggatccccgg gaattccggg gaagcttaga tccatggagc 4920 catttacaat tgaatatatc ctgccg 4946 2 4832 DNA Artificial Sequence misc_feature (1)..(4832) T-DNA of Plasmid pTHW118 2 aattacaacg gtatatatcc tgccagtact cggccgtcga actcggccgt cgagtacatg 60 gtcgataaga aaaggcaatt tgtagatgtt aattcccatc ttgaaagaaa tatagtttaa 120 atatttattg ataaaataac aagtcaggta ttatagtcca agcaaaaaca taaatttatt 180 gatgcaagtt taaattcaga aatatttcaa taactgatta tatcagctgg tacattgccg 240 tagatgaaag actgagtgcg atattatgtg taatacataa attgatgata tagctagctt 300 agctcatcgg gggatcctag acgcgtgaga tcagatctcg gtgacgggca ggaccggacg 360 gggcggtacc ggcaggctga agtccagctg ccagaaaccc acgtcatgcc agttcccgtg 420 cttgaagccg gccgcccgca gcatgccgcg gggggcatat ccgagcgcct cgtgcatgcg 480 cacgctcggg tcgttgggca gcccgatgac agcgaccacg ctcttgaagc cctgtgcctc 540 cagggacttc agcaggtggg tgtagagcgt ggagcccagt cccgtccgct ggtggcgggg 600 ggagacgtac acggtcgact cggccgtcca gtcgtaggcg ttgcgtgcct tccaggggcc 660 cgcgtaggcg atgccggcga cctcgccgtc cacctcggcg acgagccagg gatagcgctc 720 ccgcagacgg acgaggtcgt ccgtccactc ctgcggttcc tgcggctcgg tacggaagtt 780 gaccgtgctt gtctcgatgt agtggttgac gatggtgcag accgccggca tgtccgcctc 840 ggtggcacgg cggatgtcgg ccgggcgtcg ttctgggtcc attgttcttc tttactcttt 900 gtgtgactga ggtttggtct agtgctttgg tcatctatat ataatgataa caacaatgag 960 aacaagcttt ggagtgatcg gagggtctag gatacatgag attcaagtgg actaggatct 1020 acaccgttgg attttgagtg tggatatgtg tgaggttaat tttacttggt aacggccaca 1080 aaggcctaag gagaggtgtt gagaccctta tcggcttgaa ccgctggaat aatgccacgt 1140 ggaagataat tccatgaatc ttatcgttat ctatgagtga aattgtgtga tggtggagtg 1200 gtgcttgctc attttacttg cctggtggac ttggcccttt ccttatgggg aatttatatt 1260 ttacttacta tagagctttc ataccttttt tttaccttgg atttagttaa tatataatgg 1320 tatgattcat gaataaaaat gggaaatttt tgaatttgta ctgctaaatg cataagatta 1380 ggtgaaactg tggaatatat atttttttca tttaaaagca aaatttgcct tttactagaa 1440 ttataaatat agaaaaatat ataacattca aataaaaatg aaaataagaa ctttcaaaaa 1500 acagaactat gtttaatgtg taaagattag tcgcacatca agtcatctgt tacaatatgt 1560 tacaacaagt cataagccca acaaagttag cacgtctaaa taaactaaag agtccacgaa 1620 aatattacaa atcataagcc caacaaagtt attgatcaaa aaaaaaaaac gcccaacaaa 1680 gctaaacaaa gtccaaaaaa aacttctcaa gtctccatct tcctttatga acattgaaaa 1740 ctatacacaa aacaagtcag ataaatctct ttctgggcct gtcttcccaa cctcctacat 1800 cacttcccta tcggattgaa tgttttactt gtaccttttc cgttgcaatg atattgatag 1860 tatgtttgtg aaaactaata gggttaacaa tcgaagtcat ggaatatgga tttggtccaa 1920 gattttccga gagctttcta gtagaaagcc catcaccaga aatttactag taaaataaat 1980 caccaattag gtttcttatt atgtgccaaa ttcaatataa ttatagagga tatttcaaat 2040 gaaaacgtat gaatgttatt agtaaatggt caggtaagac attaaaaaaa tcctacgtca 2100 gatattcaac tttaaaaatt cgatcagtgt ggaattgtac aaaaatttgg gatctactat 2160 atatatataa tgctttacaa cacttggatt tttttttgga ggctggaatt tttaatctac 2220 atatttgttt tggccatgca ccaactcatt gtttagtgta atactttgat tttgtcaaat 2280 atatgtgttc gtgtatattt gtataagaat ttctttgacc atatacacac acacatatat 2340 atatatatat atatattata tatcatgcac ttttaattga aaaaataata tatatatata 2400 tagtgcattt tttctaacaa ccatatatgt tgcgattgat ctgcaaaaat actgctagag 2460 taatgaaaaa tataatctat tgctgaaatt atctcagatg ttaagatttt cttaaagtaa 2520 attctttcaa attttagcta aaagtcttgt aataactaaa gaataataca caatctcgac 2580 cacggaaaaa aaacacataa taaatttgaa tttcgaccgc ggtacccgga attcgagctc 2640 ggtacccggg gatcttcccg atctagtaac atagatgaca ccgcgcgcga taatttatcc 2700 tagtttgcgc gctatatttt gttttctatc gcgtattaaa tgtataattg cgggactcta 2760 atcataaaaa cccatctcat aaataacgtc atgcattaca tgttaattat tacatgctta 2820 acgtaattca acagaaatta tatgataatc atcgcaagac cggcaacagg attcaatctt 2880 aagaaacttt attgccaaat gtttgaacga tctgcttcgg atcctctaga ccaagcttgc 2940 gggtttgtgt ttccatattg ttcatctccc attgatcgta ttaagaaagt atgatggtga 3000 tgtcgcagcc ttccgctttc gcttcacgga aaacctgaag cacactctcg gcgccatttt 3060 cagtcagctg cttgctttgt tcaaactgcc tccattccaa aacgagcggg tactccaccc 3120 atccggtcag acaatcccat aaagcgtcca ggttttcacc gtagtattcc ggaagggcaa 3180 gctccttttt caatgtctgg tggaggtcgc tgatacttct gatttgttcc ccgttaatga 3240 ctgctttttt catcggtagc taatttcttt aagtaaaaac tttgatttga gtgatgatgt 3300 tgtactgtta cacttgcacc acaagggcat atatagagca caagacatac acaacaactt 3360 gcaaaactaa cttttgttgg agcatttcga ggaaaatggg gagtagcagg ctaatctgag 3420 ggtaacatta aggtttcatg tattaatttg ttgcaaacat ggacttagtg tgaggaaaaa 3480 gtaccaaaat tttgtctcac cctgatttca gttatggaaa ttacattatg aagctgtgct 3540 agagaagatg tttattctag tccagccacc caccttatgc aagtctgctt ttagcttgat 3600 tcaaaaactg atttaattta cattgctaaa tgtgcatact tcgagcctat gtcgctttaa 3660 ttcgagtagg atgtatatat tagtacataa aaaatcatgt ttgaatcatc tttcataaag 3720 tgacaagtca attgtccctt cttgtttggc actatattca atctgttaat gcaaattatc 3780 cagttatact tagctagata tccaattttg aataaaaata gctcttgatt agtaaaccgg 3840 atagtgacaa agtcacatat ccatcaaact tctggtgctc gtggctaagt tctgatcgac 3900 atggggttaa aatttaaatt gggacacata aatagcctat ttgtgcaaat ctccccatcg 3960 aaaatgacag attgttacat ggaaaacaaa aagtcctctg atagaagtcg caaagtatca 4020 caattttcta tcgagagata gattgaaaga agtgcaggga agcggttaac tggaacataa 4080 cacaatgtct aaattaattg cattcgctaa ccaaaaagtg tattactctc tccggtccac 4140 aataagttat tttttggccc tttttttatg gtccaaaata agtgagtttt ttagatttca 4200 aaaatgattt aattattttt ttactacagt gcccttggag taaatggtgt tggagtatgt 4260 gttagaaatg tttatgtgaa gaaatagtaa aggttaatat gatcaatttc attgctattt 4320 aatgttaaaa tgtgaatttc ttaatctgtg tgaaaacacc aaaaaatcac ttattgtgga 4380 ccggagaaag tatataaata tatatttgga agcgactaaa aataaacttt tctcatatta 4440 tacgaaccta aaaacagcat atggtagttt ctagggaatc taaatcacta aaattaataa 4500 aagaagcaac aagtatcaat acatatgatt tacaccgtca aacacgaaat tcgtaaatat 4560 ttaatataat aaagaattaa tccaaatagc ctcccaccct atkacttaaa ctaaaaataa 4620 ccagcgaatg tatattatat gcataattta tatattaaat gtgtataatc atgtataatc 4680 aatgtataat ctatgtatat ggttagaaaa agtaaacaat taatatagcc ggctatttgt 4740 gtaaaaatcc ctaatataat cgcgacggat ccccgggaat tccggggaag cttagatcca 4800 tggagccatt tacaattgaa tatatcctgc cg 4832 3 60 DNA Artificial Sequence misc_feature (1)..(60) Primer 248 3 catgccctga cccaggctaa gtattttaac tttaaccact ttgctccgac agtcccattg 60 4 60 DNA Artificial Sequence misc_feature (1)..(60) primer 249 4 caatgggact gtcggaggac tgagggccaa agcttggctc ttagcctggg tcagggcatg 60 5 26 DNA Artificial Sequence misc_feature (1)..(26) primer 247 5 ccgtcaccga gatctgatct cacgcg 26 6 24 DNA Artificial Sequence misc_feature (1)..(24) primer 250 6 gcactgaggg ccaaagcttg gctc 24 7 25 DNA Artificial Sequence misc_feature (1)..(25) primer 251 7 ggatcccccg atgagctaag ctagc 25 8 21 DNA Artificial Sequence misc_feature (1)..(21) primer 254 8 cttagcctgg gtcagggcat g 21 9 20 DNA Artificial Sequence misc_feature (1)..(20) primer 258 9 ctacggcaat gtaccagctg 20 10 23 DNA Artificial Sequence misc_feature (1)..(23) primer SP6 10 taatacgact cactataggg cga 23 11 22 DNA Artificial Sequence misc_feature (1)..(22) primer T7 11 tttaggtgac actatagaat ac 22 12 21 DNA Artificial Sequence misc_feature (1)..(21) primer 201(BNA01) 12 gcttggacta taatacctga c 21 13 953 DNA Brassica napus misc_feature (1)..(953) “n” can be any nucleotide a,c,t or g 13 cccngccgcc atggccgcgg gattcttagc ctgggtcagg gcatgcatgg tgtgatccaa 60 agactttctc ggcccaaata ctaatcatca caagtcatgc atgatctgct cgggatggcc 120 aagaaaaatc gaacccatga caatattcac agttgtaagt tttttaccag tagacaaata 180 ccacttggtt taacatattg taaacttaat atatagaaga tgttcctatt cagaaaataa 240 tatatgtata tatataaaat tttattggcg actcgaggat gcacagaaat ataaaatgtt 300 ggtcgcttag accatctcca atgtatttct ctatttttac ctctaaaata aaggagctct 360 ataatagagg tgggttttgc tccaatgtat ttctttaaaa tagagatctc tacatataga 420 gcaaaatata gaggaatgtt atttcttcct ctataaatag aggagaaaat agcaatctct 480 attttagagg caaaaataga gatbsgttgg agtgattttg cctctaaatg ctattataga 540 ggtagaaata gaggtgggtt ggagatgctc ttactatttt catagtaggt gaaaacttga 600 aactagaaag ctttggagtg tacgagtgga aaacctctct ttgtagaaac atacacatgc 660 catttagtta actagttgac atagattttt gagtcagata actttaagaa tatatatgtt 720 tggatgagag tttgacactt tgagccactc gaaggacaaa ttttaaaaac ttgtgggatg 780 ctgtggccat aaaccttgag gacvstttga tcatattcta ttaactacag tacgaatatg 840 attcgacctt tgcaattttc tcttcaggta ctcggccgtc gaactcggcc gtcgagtaca 900 tggtcgataa gaaaaggcaa tttgtagatg ttaattccca tcttgaaaga aat 953 14 16 DNA Artificial Sequence misc_feature (1)..(16) “n” stands for any nucleotide “s” stands for either nucleotide g or c “w” stands for nucleotide a or t/u 14 ngtcgaswgt ntwcaa 16 15 22 DNA Artificial Sequence misc_feature (1)..(15) primer 259 15 gtgcagggaa gcggttaact gg 22 16 22 DNA Artificial Sequence misc_feature (1)..(22) primer 260 16 cctttggagt aaatggtgtt gg 22 17 20 DNA Artificial Sequence misc_feature (1)..(20) primer 24 17 gcgaatgtat attatatgca 20 18 537 DNA Brassica napus misc_feature (1)..(537) “n” stands for any nucleotide a,c,g or t 18 gcgaatgtat attatatgca taatttatat attaaatgtg tataatcatg tataatcaat 60 gtataatcta tgtatatggt tagaaaaagt aaacaattaa tatagccggc tatttgtgta 120 aaaatcccta atataatcga cggatccccg ggaattccgg gggaagctta gatccatgga 180 tttgttatga taaccaaaaa caccctcctt tttattataa aggtagggat agctaatctg 240 ttattcggtt ttgattagag atattaatcc cgttttatca agtacagttt gatgtatttt 300 tttgttcgtt ttcattacaa tccaagacaa gttaggttta ttacatttta ccaaaaaaaa 360 aggtttggtt tattgtgaac attgctgcgg tttatttaaa tttgattcta ttcaaaggtc 420 aatccgtatt taacaagtaa actagtcttt atataatctt aaatctaacg atctttgatt 480 tttaaattgc atttanctat gtcctctctg gcgtatatgg tctctttgaa aacactc 537 19 19 DNA Artificial Sequence misc_feature (1)..(18) primer 51 (BN02) 19 tgacactttg agccactcg 19 20 20 DNA Artificial Sequence misc_feature (1)..(20) primer 48 20 ggagggtgtt tttggttatc 20 21 178 DNA Brassica napus misc_feature (1)..(178) sequence comprising the target site deletion of MS-BN1 21 gacactttga gccactcgaa ggacaaattt taaaaacttg tgggatgctg tggccataaa 60 ccttgaggac gctttgatca tattctatta actacagtac gaatatgatt cgacctttgc 120 aattttctct tgttttctaa ttcatatgga tttgttatga taaccaaaaa caccctcc 178 22 1198 DNA Artificial Sequence misc_feature (1)..(1198) insertion region of MS-BN1 22 catggtgtga tccaaagact ttctcggccc aaatactaat catcacaagt catgcatgat 60 ctgctcggga tggccaagaa aaatcgaacc catgacaata ttcacagttg taagtttttt 120 accagtagac aaataccact tggtttaaca tattgtaaac ttaatatata gaagatgttc 180 ctattcagaa aataatatat gtatatatat aaaattttat tggcgactcg aggatgcaca 240 gaaatataaa atgttggtcg cttagaccat ctccaatgta tttctctatt tttacctcta 300 aaataaagga gctctataat agaggtgggt tttgctccaa tgtatttctt taaaatagag 360 atctctacat atagagcaaa atatagagga atgttatttc ttcctctata aatagaggag 420 aaaatagcaa tctctatttt agaggcaaaa atagagatbs gttggagtga ttttgcctct 480 aaatgctatt atagaggtag aaatagaggt gggttggaga tgctcttact attttcatag 540 taggtgaaaa cttgaaacta gaaagctttg gagtgtacga gtggaaaacc tctctttgta 600 gaaacataca catgccattt agttaactag ttgacataga tttttgagtc agataacttt 660 aagaatatat atgtttggat gagagtttga cactttgagc cactcgaagg acaaatttta 720 aaaacttgtg ggatgctgtg gccataaacc ttgaggacvs tttgatcata ttctattaac 780 tacagtacga atatgattcg acctttgcaa ttttctcttc aggttttcta attcatatgg 840 atttgttatg ataaccaaaa acaccctcct ttttattata aaggtaggga tagctaatct 900 gttattcggt tttgattaga gatattaatc ccgttttatc aagtacagtt tgatgtattt 960 ttttgttcgt tttcattaca atccaagaca agttaggttt attacatttt accaaaaaaa 1020 aaggtttggt ttattgtgaa cattgctgcg gtttatttaa atttgattct attcaaaggt 1080 caatccgtat ttaacaagta aactagtctt tatataatct taaatctaac gatctttgat 1140 ttttaaattg catttancta tgtcctctct ggcgtatatg gtctctttga aaacactc 1198 23 22 DNA Artificial Sequence misc_feature (1)..(22) primer 193 (BN03) 23 tcatctacgg caatgtacca gc 22 24 1077 DNA Brassica napus misc_feature (1)..(1077) sequence comprising the 5′ flanking region of RF-BN1 24 gagctctccc atatggtcga cctgcaggcg gccgcactag tgattcttag cctgggtcag 60 ggcatggcat gtctgatggt acatgctaaa tgctatattt cctgtttaaa gtgttaaaat 120 cattttctga tggaactaaa tccagtttta agagtaactg acaagtacaa ttaagcacaa 180 caatataata gtagtaattg gcatctttga ttgttaaata tcaaaacagt aaagttacaa 240 aaaaaaatac caaaccaata atgaagactt ggcggagaca gtgccgtgcg aaggttttcg 300 gaggtccgag acgagttcaa aaatacattt tacataatat atttttcata tatatatata 360 tataacattc aaaagtttga attattacat aaacgttttc taaattttct tcaccaaaat 420 tttataaact aaatttttaa atcatgaaca aaaagtatga atttgtaata taaatacaaa 480 gatacaaatt tttgattgaa atattggtag ctgtcaaaaa agtaaatctt agaatttaaa 540 ttaactatag taaactatat attgaaaata ttataaattt ttatcaaatt ctcataaata 600 tataaaataa atctaactca tagcatataa aaagaagact aatgtggatc aaaatattta 660 cagtttttta gaagtagaat ctttatagtt ttatttaaaa tatagcaaaa atgatcacaa 720 acctagttay ttaaggagaa gtccaattca aaatcaaata aaaataaaat ctatctaaaa 780 aaatatgtta actaccatgc aaaagtattt tttttgtaat tagaaaccct gaaatttgta 840 caaaacttgg acccctaggt aaatgccttt ttcatctcgc gataagaaaa ggcaatttgt 900 agatgttaat tcccatcttg aaagaaatat agtttaaata tttattgata aaataacaag 960 tcaggtatta tagtccaagc aaaaacataa atttattgat gcaagtttaa attcagaaat 1020 atttcaataa ctgattatat cagctggtac atcgccgtag aatcccgcgc catggcg 1077 25 16 DNA Artificial Sequence misc_feature (1)..(16) “n” stands for any nucleic acid “s” stands for G or C “w” stands for A or T/U 25 ntgcgaswga nawgaa 16 26 19 DNA Artificial Sequence misc_feature (1)..(19) primer 314 26 gtaggaggtt gggaagacc 19 27 25 DNA Artificial Sequence misc_feature (1)..(25) primer 315 27 gggctttcta ctagaaagct ctcgg 25 28 24 DNA Artificial Sequence misc_feature (1)..(24) primer 316 28 ccgataggga agtgatgtag gagg 24 29 21 DNA Artificial Sequence misc_feature (1)..(21) primer 288 29 atgcagcaag aagcttggag g 21 30 1501 DNA Brassica napus misc_feature (1)..(1501) “n” stands for any nucleotide a,c,g or t 30 ccatggccgc gggattgtag gaggttggga agacaggccc agaaagagat ttatctgact 60 cgttttgtgt atagttttca atgttcataa aggaagatgg agacttgaga agtttttttt 120 ggactttgtt tagctttgtt gggcgttttt tttttttgat caataacttt gttgggctta 180 tggtcgataa gcgtgcgcat gtctgatggt acatgctaaa tgctatattt ctgtttaaag 240 tgttaaaatc attttctgat ggaactaaat ccagttttaa gagtaactga caagtacaat 300 taagcacaac aataaaatag tagtaattgg catctttgat tgttaaatat caaaacaata 360 aagttacaaa aaaaaatacc aaaccaataa tgaagacttg gcggagacag tgccgtgcga 420 aggttttcgg aggtccgaga cgagttcaaa aatacatttt acataatata tttttcatat 480 atatatatat atataacatt caaaagtttg aattattaca taaacgtttt ctaaattttc 540 ttcaccaaaa ttttataaac taaaattttt maatcatgaa caaaaagtat gaatttgtaa 600 tataaatacm aagatacaaa tttttgattg aaatattggt agctgtcaaa aaagtaaatc 660 ttagaattta aattaactat agtaaactat atatggaaaa tattataaat ttttatcaaa 720 ttctcataaa tatataaaat aaatctaact catagcatat aaaaagaaga ctaatgtgga 780 tcaaratatt tacagttttt tagaagtaga atctctatag ttttatttaa aatatagcaa 840 aaatgatcac aaacctagtt actttaacca gaagtccaat tcaaaatcaa ataaaaataa 900 aaatctatct aaaaaaatat gttaactacc atgcaaaagt attttttttt gtaattagaa 960 accctgaaat ttgtacaaaa cttggacccc taggtaaatt ccctagaaag tatcctatta 1020 gcgtcgacaa actgttgctc atatttttct ctccttactt tatatcatac actaatatan 1080 gnagatgatc taattaatta ttcatttcca tgctagctaa ttcaagaaaa agaaaaaaaa 1140 ctattatcta aacttatatt cgagcaacac ctcggagata acaggatata tgtcattaat 1200 gaatgcttga actcatctcg cgaactcatc tcgcatcgct tatagccaca aagatccaac 1260 ccctctcttc aatcatatat cagtagtaca atacaaatag atattgtgag cacatatgcc 1320 gtctagtact gatgtgtaca tgtagaggag ccgcaaatgt ttagtcactc caacaaatga 1380 gcatgaccac gcatcttctg atgatgtaca gccgtccctt ttgctctctc aaatatcctc 1440 caagcttctt gctgcataaa tcactagtgc ggccgcctgc aggtcgacca tatgggagag 1500 c 1501 31 21 DNA Artificial Sequence misc_feature (1)..(21) primer 269 31 ggttttcgga ggtccgagac g 21 32 21 DNA Artificial Sequence misc_feature (1)..(283) primer 283 32 cttggacccc taggtaaatg c 21 33 22 DNA Artificial Sequence misc_feature (1)..(22) primer 284 33 gtacaaaact tggaccccta gg 22 34 1068 DNA Brassica napus misc_feature (1)..(1068) “n” stands for any nucleotide a,c,g or t 34 cgcgttggga gctctcccat atggtcgacc tgcaggcggc cgcactagtg attcttggac 60 ccctaggtaa atgccttttt caaaagcctc taagcacggt tctgggcggg gagtcagcga 120 gaaaaaaaga tatttcccta gaaagtatcc tattagcgtc gacaaactgt tgctcatatt 180 tttctctcct tactttatat catacactaa tataaaaaga tgatctaatt aattattcat 240 ttccatgcta gctaattcaa gaaaaagaaa aaaactatta tctaaactta tattcgagca 300 acacctcgga gataacagga tatatgttat taatgaatgc ttgaactcat ctcgcgaact 360 catctcgcat cgcttatagc cacaaagatc caacccctct cttcaatcat atatcagtag 420 tacaatacaa atagatattg tgagcacata tgccgtctag tactgatgtg tatatgtaga 480 gganngcaaa tgtttagtca ctccaacaaa tgagcatgac nacgcatctt ctgatgatgt 540 acagccgtcc cttttgctct ctcaaatatc ctccaagctt cttgctgcat ggaatcttct 600 tcttggtgtc tttcatgata acaaaatcta acgagagaga aacccttagt caagaaaaaa 660 caaataaaac tctaacgaga gtgtgtgaga aagtagagag tatgtgtgag tgacggagag 720 aaagtgagac cataaagatg ttgtgcaaag agagcaagac ttaacctata tatactcaca 780 tacacgtaca catcataccc attanagata ataaaaagga aaaaggaaca actaacaagg 840 gaactgtatc ccatacttta tctcatcata catgatgcat aatatattct ttcgtatatc 900 aagaaaaatg agcctgatat ttttttattt cgaaactaaa agagtgtcta tttctctctc 960 ttagagatag tgccatgtca aatttctaag aagtagcaag atttacaaag gaatctaaag 1020 caaccccacg cgcattgtgt tcatttctct cgaccatccc gcggccat 1068 35 21 DNA Artificial Sequence misc_feature (1)..(21) primer 57 35 gcatgatctg ctcgggatgg c 21 36 909 DNA Artificial sequence misc_feature (1)..(909) sequence comprising the 5′ flanking region of MS-BN1 in WOSR 36 tgcatgatct gctcgggatg gccaagaaaa atcgaaccca tgacaatatt cacagttgta 60 agttttttac cagtagacaa ataccacttg gtttaacata ttgtaaactt aatatataga 120 agatgttcct attcagaaaa taatatatgt atatatataa aattttattg gcgactcgag 180 gatgcacaga aatataaaat gttggtcgct tagaccatct ccaatgtatt tctctatttt 240 tacctctaaa ataaaggaac tctataatag aggtgggttt tactccaatg tatttcttta 300 aaatagagat ctctacatat agagcaaaat atagaggaat gttatttctt cctctataaa 360 tagaggagaa aatagcaatc tctattttag aggcaaaaat agagatgggt tggagtgatt 420 ttgcctctaa atgctattat agaggtagaa atagaggtgg gttggagatg ctcttactat 480 tttcatagta ggtgaaaact tgaaactaga aagctttgga gtgtacgagt ggaaaacctc 540 tctttgtaga aacatacaca tgccatttag ttaactagtt gacatagatt tttgagtcag 600 ataactttaa gaatatatat gtttggatga gagtttgaca ctttgagcca ctcgaaggac 660 aaattttaaa aacttgtggg atgctgtggc ccataaacct tgaggacgct ttgatcatat 720 tctattaact acagtacgaa tatgattcga cctttgcaat tttctcttca gtactcggcc 780 gtcgaactcg gccgtcgagt acatggtcga taagaaaagg caatttgtag atgttaattc 840 ccatcttgaa agaaatatag tttaaatatt tattggataa aataacaagt caggtattat 900 agtccaagc 909 37 20 DNA Artificial Sequence misc_feature (1)..(20) primer 68 37 ccatatacgc cagagaggac 20 38 522 DNA Brassica napus misc_feature (1)..(522) sequence comprising the 3′ flanking region of MS-BN1 in WOSR 38 gcgaatgtat attatatgca taatttatat attaaatgtg tataatcatg tataatcaat 60 gtataatcta tgtatatggt tagaaaaagt aaacaattaa tatagccggc tatttgtgta 120 aaaatcccta atataatcga cggatccccg ggaattccgg gggaagctta gatccatgga 180 tttgttatga taaccaaaaa caccctcctt tttattataa aggtagggat agctaatctg 240 ttattcggtt ttgattagag atattaatcc cgttttatca agtacagttt gatgtatttt 300 tttgttcgtt ttcattacaa tccaagacaa gttaggttta ttacatttta ccaaaaaaaa 360 aggtttggtt tattgtgaac attgctgcgg ttttatttaa atttgattct attcaaaggt 420 caatccgtat ttaacaagta aactagtctt tatataatct taaatctaac gatacttgga 480 tttttaaatt gcatttagct atgtcctctc tggcgtatat gg 522 39 694 DNA Brassica napus misc_feature (1)..(694) sequence comprising the 5′ flanking region of RF-BN1 in WOSR 39 ggttttcgga ggtccgagac gagttcaaaa atacatttta cataatatat ttttcatata 60 tatatatata tataacattc aaaagtttga attattacat aaacgttttc taaattttct 120 tcaccaaaat tttataaact aaaattttta aatcatgaac aaaaagtatg aatttgtaat 180 ataaatacaa agatacaaat ttttgattga aatattggta gctgtcaaaa aagtaaatct 240 tagaatttaa attaactata gtaaactata tattgaaaat attataaatt tttatcaaat 300 tctcataaat atataaaata aatctaactc atagcatata aaaagaagac taatgtggat 360 caaaatattt acagtttttt agaagtagaa tctttatagt tttatttaaa atatagcaaa 420 aatgatcaca aacctagtta ctttaaccag aagtccaatt caaaatcaaa taaaaataaa 480 aatctatcta aaaaaatatg ttaactacca tgcaaaagta tttttttttg taattagaaa 540 ccctgaaatt tgtacaaaac ttggacccct aggtaaatgc ctttttcatc tcgcgataag 600 aaaaggcaat ttgtagatgt taattcccat cttgaaagaa atatagttta aatatttatt 660 gataaaataa caagtcaggt attatagtcc aagc 694 40 1279 DNA Brassica napus misc_feature (1)..(1279) sequence comprising the 3′ flanking region of RF-BN1 in WOSR 40 gggggttttt ttttttgatc aataactttg ttgggcttat ggtcgataag cgtgcgcatg 60 tctgatggta catgctaaat gctatatttc tgtttaaagt gttaaaatca ttttctgatg 120 gaactaaatc cagttttaag agtaactgac aagtacaatt aagcacaaca ataaaatagt 180 agtaattggc atctttgatt gttaaatatc aaacaataaa gttcaaaaaa aaataccaac 240 ccaataatga agacttggcg gagacagtgc cgtgcgaagg ttttcggagg tccgagacga 300 gttcaaaaat acattttaca taatatattt ttcatatata tatatatata taacattcaa 360 aagtttgaat tattacataa acgttttcta aattttcttc accaaaattt tataaactaa 420 aatttttaaa tcatgaacaa aaagtatgaa tttgtaatat aaatacaaag atacaaattt 480 ttgattgaaa tattggtagc tgtcaaaaaa gtaaatctta gaatttaaat taactatagt 540 aaactatata ttgaaaatat tataaatttt tatcaaattc tcataaatat ataaaataaa 600 tctaactcat agcatataaa aagaagacta atgtggatca aaatatttac agttttttag 660 aagtagaatc tttatagttt tatttaaaat atagcaaaaa tgatcacaaa cctagttact 720 ttaaccagaa gtccaattca aaatcaaata aaaataaaaa tctatctaaa aaaatatgtt 780 aactaccatg caaaagtatt tttttttgta attagaaacc ctgaaatttg tacaaaactt 840 ggacccctag gtaaattccc tagaaagtat cctattagcg tcgacaaact gttgctcata 900 tttttctctc cttactttat atcatacact aatataaaaa gatgatctaa ttaattattc 960 atttccatgc tagctaattc aagaaaaaga aaaaaaactt attatctaaa cttatattcg 1020 agcaacacct cggagataac aggatatatg tcattaatga atgcttgaac tcatctcgcg 1080 aactcatctc gcatcgctta tagccacaaa gatccaaccc ctctcttcaa tcatatatca 1140 gtagtacaat acaaatagat attgtgagca catatgccgt ctagtactga tgtgtatatg 1200 tagaggagcc gcaaatgttt agtcactcca acaaatgagc atgaccacgc atcttctgat 1260 gatgtacagc cgtcccttt 1279 41 20 DNA Artificial Sequence misc_feature (1)..(20) primer 268 ( BNA 04) 41 tggaccccta ggtaaatgcc 20 42 22 DNA Artificial Sequence misc_feature (1)..(22) prmer BNA05 42 aacgagtgtc agctagacca gc 22 43 22 DNA Artificial Sequence misc_feature (1)..(22) primer BNA06 43 cgcagttctg tgaacatcga cc 22 44 11 DNA Artificial Sequence misc_feature (1)..(11) filler DNA sequence 44 tcatctcgcg a 11 

We claim:
 1. A plant, seed, plant cells or tissue of winter oilseed rape (WOSR), wherein the genomic DNA of said plant, seed, plant cells or tissue, yields a DNA fragment of between 195 and 235 bp, using the RF-BN1 Elite Event Polymerase Chain reaction Identification Protocol with two primers having the nucleotide sequence of SEQ ID No 23 and SEQ ID No 41 respectively.
 2. The plant, or seed, plant cells or tissue thereof, of claim 1, wherein the genomic DNA of the WOSR plant, or seed, plant cells or tissues thereof yields at least two sets of restriction fragments selected from the group consisting of: i) one set of Bam HI fragments, wherein one has a length of between 805 and 1099 bp, preferably of about 814 bp, one has a length between 1700 and 1986 bp, one has a length between 2450 and 2838 bp, and one has a length between 5077 and 14057 bp; ii) one set of Eco RI fragments, one with a length of between 805 and 1159 bp, one with a length between 1986 and 2450 bp, and two with a length of between 5077 and 14057 bp; iii) one set of Eco RV fragments wherein both have a length of between 5077 and 14057 bp; and iv) one set of Hind III fragments, wherein one has a length of between 1700 and 2140 bp, and two have a length between 2450 and 2838 bp; wherein each of the restriction fragments hybridizes under standard stringency conditions, with the 2182 bp fragment comprising the PTA29-barstar sequence obtained by HpaI digestion of the plasmid pTHW118 (SEQ ID NO: 2).
 3. The plant, seed, plant cells or tissue of claim 2, wherein the genomic DNA of said plant, seed, plant cells or tissues yields at least three sets of restriction fragments selected from said group.
 4. The plant, seed, plant cells or tissue of claim 3, wherein the genomic DNA of said plant, seed, plant cells or tissues yields at least four sets of restriction fragments selected from said group.
 5. The plant, seed, plant cells or tissue of claim 1, wherein the genomic DNA yields a DNA fragment of 215 bp using the PCR with two primers having the nucleotide sequence of SEQ ID NO: 23 and SEQ ID NO: 41 respectively.
 6. The plant, seed, plant cells or tissue of claim 1, the genomic DNA of said plant, cell, tissue or seed yields at least three sets of restriction fragments are selected from the group consisting of: i) one set of EcoRI fragments, one with a length of between 2140 and 2450 bp, preferably of about 2266 bp, and one with a length of more than 14 kbp; ii) one set of EcoRV fragments wherein one has a length of between 1159 and 1700 bp, preferably of about 1.4 kbp and the other has a length of more than 14 kbp; iii) one set of Hpa 1 fragments, one with a length of between 1986 and 2140 bp, preferably with a length of about 1990 bp, and one with a length of between 2140 and 2450 bp, preferably of about 2229 bp; iv) one set of Afl III fragments, one with a length of between 514 and 805 bp, preferably with a length of about 522 bp, and one with a length of between 2140 and 2450 bp, preferably about 2250 bp, and one with a length of between 2450 and 2838 bp, preferably of about 2477 bp; and v) one set of Nde I fragments, both with a length of between 5077 and 14057 bp, preferably one of about 6500 bp, and one with a length of about 10 kbp; wherein each of the restriction fragments hybridizes under standard stringency conditions, with the 3942 bp fragment comprising the PTA29-bamase sequence obtained by Hind III digestion of the plasmid pTHW 107 (SEQ ID NO: 1).
 7. The plant, seed, plant cells or tissue of claim 6, wherein the genomic DNA of said plant, seed, plant cells or tissues yields at least four sets of restriction fragments selected from said group.
 8. The plant, seed, plant cells or tissue of claim 7, wherein the genomic DNA of said plant, seed, plant cells or tissues yields at least all five sets of restriction fragments selected from said group.
 9. The plant, seed, plant cells or tissue of claim 1, further wherein the genomic DNA yields a DNA fragment of between 260 and 300 bp, using the Identification Protocol with two primers having the nucleotide sequence of SEQ ID NO: 12 and SEQ ID NO: 19 respectively.
 10. The plant, plant cells or tissue of claim 1, obtained from the seed deposited at the ATCC under accession number PTA-730.
 11. A plant, seed, plant cell or plant tissue of a hybrid plant produced from the plant of claim
 1. 12. The seed deposited at the ATCC under accession number PTA-730.
 13. A process for producing the transgenic WOSR plant cell or plant of claim 1, which comprises inserting a recombinant DNA molecule into a part of the chromosomal DNA of a WOSR cell characterized by the sequence of SEQ ID NO: 34 and, optionally regenerating a WOSR plant from the transformed WOSR cell.
 14. A transgenic WOSR seed comprising elite event RF-BN1, seed comprising RF-BN1 having been deposited as ATCC accession number PTA-730.
 15. A plant, cell or tissue therefrom derived from the seed of claim
 14. 